CN109923691B

CN109923691B - Seal for high temperature reactive material device

Info

Publication number: CN109923691B
Application number: CN201780068872.3A
Authority: CN
Inventors: 大卫·J·布拉德韦尔; 大卫·A·H·麦克利里; 格雷戈里·A·汤普森; 艾伦·布兰查德; 杰弗里·B·米勒; 罗纳德·蒂尔; 威廉·B·朗豪斯; 亚历山大·W·艾略特; 唐纳德·R·萨多韦; 迈克尔·麦克尼利; 伊恩·雷德芬
Original assignee: Ambri Inc
Current assignee: Ambri Inc
Priority date: 2016-09-07
Filing date: 2017-09-07
Publication date: 2022-05-17
Anticipated expiration: 2037-09-07
Also published as: JP2019526909A; EP3510647A4; CN109923691A; JP7349355B2; US20190296276A1; WO2018052797A2; WO2018052797A3; CN115020885A; EP3510647A2

Abstract

The present disclosure provides seals for devices operating at elevated temperatures and having reactive metal vapors such as lithium, sodium, or magnesium. In some examples, such devices include energy storage devices that may be used within the power grid or as part of a stand-alone system. The energy storage device may be charged from an electrical power production source for later discharge, such as when there is a demand for electrical energy consumption.

Description

Seal for high temperature reactive material device

Cross-referencing

This application claims the benefit of U.S. provisional patent application No. 62/384,662 filed 2016, 9, 7, the entire contents of which are incorporated herein by reference.

Technical Field

Various devices are configured for use at elevated temperatures (or high temperatures). Examples of such devices include elevated temperature batteries, which are devices capable of converting stored chemical energy into electrical energy. Batteries are useful in many domestic and industrial applications. Another example of a high temperature apparatus is a chemical vapor deposition chamber such as those used in the manufacture of semiconductor devices. Another example of a high temperature device is a chemical vessel, a delivery pipe, or a storage vessel designed for processing, transporting, containing, and/or storing reactive metals. Another example of a high temperature device may be any high temperature device that requires electrical isolation between two portions of the device's exterior surface in order to transmit and receive electrical energy and/or electrical signals to and from the device. These devices can typically operate at temperatures of 200 ℃ or in excess of 200 ℃.

Background

Various limitations associated with devices that increase in temperature (or high temperature devices) are recognized herein. For example, some batteries operate at high temperatures (e.g., at least about 100 ℃ or 300 ℃) and have reactive material vapors (e.g., reactive metal vapors, such as vapors of lithium, sodium, potassium, magnesium, or calcium, for example) that may be adequately contained within the device. Other examples of high temperature reactive material devices include nuclear (e.g., fusion and/or fission) reactors that use molten salts or metals (e.g., molten sodium or lithium or molten sodium or lithium-containing alloys) as coolants, devices for manufacturing semiconductors, non-uniform reactors, and devices for producing (e.g., processing) and/or handling (e.g., transporting or storing) reactive materials (e.g., reactive chemicals such as, for example, chemicals with enhanced chemical reduction capabilities, or reactive metals such as, for example, lithium or sodium). Such devices may be sufficiently sealed from the external environment during use to prevent vapors of reactive materials from exiting the device (e.g., to prevent device failure, prolong device use, or avoid adverse health effects on users or operators of such devices), and/or have a protective liner within the device to avoid corrosion of the container. Moreover, the seals of these devices themselves can be protected from the effects of use in the presence of high temperature, reactive materials.

The present disclosure provides ceramic materials that may be used in high temperature devices and/or other devices, including, for example, reinforced ceramics for ballistic resistant systems and devices (e.g., ballistic penetration resistant armor).

The present disclosure provides seals and/or reactor vessel liners for energy storage devices and other devices that have (e.g., contain or include) reactive materials (e.g., reactive metals) and operate at high temperatures (e.g., at least about 100 ℃ or 300 ℃). The energy storage device (e.g., a battery) may be used within the grid or as part of a stand-alone system. The battery may be charged from an electricity producing source for later discharge when there is a demand for electrical energy consumption.

In one aspect, the present disclosure provides a high temperature device comprising: a container comprising a lumen, wherein the lumen comprises a reactive material, and wherein the reactive material is maintained at a temperature of at least about 200 ℃; a seal that seals the interior cavity of the vessel from an environment external to the vessel, wherein the seal comprises a ceramic component, and wherein the seal is exposed to the reactive material and the environment external to the vessel; a conductor extending from the environment external to the container, through the seal, to the interior cavity of the container; and a first metal sleeve coupled to the conductor and the ceramic component, wherein the first metal sleeve is coupled to the ceramic component by a first braze joint comprising a first braze (blaze), and wherein the first braze comprises an alloy of silver and aluminum.

In some embodiments, the conductor is a negative current lead (negative current lead). In some embodiments, the device further comprises a negative current collector (negative current collector) within the container, wherein the negative current collector is in contact with the reactive material and attached to the negative current lead.

In some embodiments, the apparatus further comprises a second metal sleeve coupled to the ceramic component, wherein the second metal sleeve is coupled to the vessel or to a collar joined to the vessel, wherein the second metal sleeve is coupled to the ceramic component by a second braze joint comprising a second braze, and wherein the second braze comprises an alloy of silver and aluminum. In some embodiments, the alloy of silver and aluminum comprises a ratio of silver to aluminum of less than or equal to about 19 to 1. In some embodiments, one or both of the first braze and the second braze further comprises a titanium braze alloy. In some embodiments, the titanium brazing alloy includes about 19-21 weight percent zirconium, 19-21 weight percent nickel, 19-21 weight percent copper, and the remaining weight percent includes at least titanium.

In some embodiments, the apparatus further comprises an internal braze disposed adjacent to the first braze joint, the second braze joint, or both the first braze joint and the second braze joint, wherein the internal braze is exposed to the interior cavity of the vessel. In some embodiments, the internal braze comprises a titanium braze alloy.

In some embodiments, the second metal sleeve is coupled to the container or the collar by a third braze. In some embodiments, the third braze comprises a nickel-based or titanium-based braze, and wherein the nickel-based braze comprises greater than or equal to about 70 weight percent nickel. In some embodiments, the nickel-based braze comprises a BNi-2 braze, a BNi-5b braze, or a BNi-9 braze.

In some embodiments, the first metal sleeve is coupled to the conductor by a fourth braze. In some embodiments, the fourth braze is a nickel-based braze, a titanium-based braze, or an alloy of silver and aluminum.

In some embodiments, the alloy of silver and aluminum further comprises a wetting agent. In some embodiments, the wetting agent comprises titanium. In some embodiments, the ceramic component comprises aluminum nitride. In some embodiments, the ceramic component further comprises greater than or equal to about 3 weight percent yttria. In some embodiments, the ceramic component further comprises about 1% to about 4% by weight of yttria.

In some embodiments, the first and second metal sleeves comprise alloy 42 and the conductor or the collar comprises stainless steel. In some embodiments, the stainless steel comprises 304L stainless steel. In some embodiments, the thickness of the first and second metal sleeves is less than or equal to about 0.020 inches.

In one aspect, the present disclosure provides an electrochemical cell comprising: a container comprising a lumen, wherein the lumen comprises a reactive material, and wherein the reactive material is maintained at a temperature of at least about 200 ℃; a seal that seals the interior cavity of the vessel from an environment external to the vessel, wherein the seal comprises a ceramic component that is exposed to both the reactive material and the environment external to the vessel; a current lead extending from the interior cavity of the container through the seal to the environment outside the container; a first metal sleeve coupled to the current lead and the ceramic component; and a second metal sleeve coupled to the ceramic component and the vessel or to a collar joined to the vessel, wherein the ceramic component comprises a physical ion blocker on a surface of the ceramic component.

In some embodiments, the physical ion blocker is shaped to inhibit electromigration along the surface of the ceramic component. In some embodiments, the physical ion blocker is shaped to inhibit the formation of metal dendrites across the surface of the ceramic component. In some embodiments, the first metal sleeve and the second metal sleeve are coupled to the ceramic component by a first braze and a second braze, respectively. In some embodiments, the surface of the ceramic component is an exposed surface of the ceramic component between the first and second braze, and wherein the physical ion barrier is shaped such that a shortest path from the first braze to the second braze along the exposed surface of the ceramic component includes a path segment that is at least partially away from both the first braze and the second braze.

In some embodiments, the first and second solders each comprise an alloy of silver and aluminium. In some embodiments, the current lead is a negative current lead. In some embodiments, the physical ion blocker is attached to the surface of the ceramic component. In some embodiments, the physical ion blocker is disposed on an exposed surface of the ceramic component. In some embodiments, the physical ion blocker is an integral part of the ceramic component, wherein the physical ion blocker comprises one or more protrusions as part of the exposed surface of the ceramic component, and wherein the one or more protrusions protrude from a reference surface of the ceramic component.

In some embodiments, the one or more protrusions comprise a plurality of protrusions defining a groove. In some embodiments, the one or more protrusions extend from the reference surface of the ceramic component a distance greater than or equal to about 2 mm. In some embodiments, the one or more protrusions comprise a long dimension and a short dimension, and wherein the long dimension defines a chamfer disposed at an angle substantially normal to the reference surface of the ceramic component. In some embodiments, the one or more protrusions define a slope disposed at an acute angle relative to the reference surface of the ceramic component and facing a source of positive electric field. In some embodiments, the one or more protrusions include a first portion protruding from the reference surface of the ceramic component and a second portion defining a slope that extends parallel to the reference surface of the ceramic component and toward a source of positive electric field. In some embodiments, the positive electric field source is the body of the container in electrical communication with the positive electrode.

In one aspect, the present disclosure provides a high temperature device comprising: a container comprising a lumen, wherein the lumen comprises a reactive material, and wherein the reactive material is maintained at a temperature of at least about 200 ℃; a seal that seals the interior cavity of the vessel from an environment external to the vessel, wherein the seal comprises a ceramic component, and wherein the seal is exposed to both the reactive material and the environment external to the vessel; a conductor extending from the environment external to the container, through the seal, to the interior cavity of the container; a metal sleeve coupled to the conductor and the ceramic component, wherein the metal sleeve is coupled to the ceramic component by a braze joint comprising a braze, and wherein the braze is formed of a material that is substantially non-reactive with air and prevents diffusion of air into the vessel when the reactive material is maintained at a temperature of at least about 200 ℃ for a period of at least about 1 day.

In some embodiments, the braze is ductile. In some embodiments, the device further comprises an internal braze, and wherein the internal braze contacts and protects the braze from the reactive material. In some embodiments, the internal braze is a reactive metal braze. In some embodiments, the diffusion of air into the container is at most about 1x10^-8Atmospheric pressure-cubic centimeters per second. In some embodiments, the braze is an alloy of at least two different metals.

In one aspect, the present disclosure provides a high temperature device comprising: a vessel having a chamber containing a reactive material comprising a gas portion and a liquid portion, the reactive material being maintained at a temperature of at least about 200 ℃; a seal sealing the chamber of the vessel from an environment external to the vessel, wherein the seal comprises a ceramic component exposed to the gaseous portion; a conductor extending through the seal from the external environment of the container to the chamber of the container, wherein the conductor is in electrical communication with the liquid portion; a first shield connected to the conductor and disposed within the gas portion between the seal and the liquid portion.

In some embodiments, the first shield at least partially blocks the seal and the liquid portion from each other. In some embodiments, the first shield completely blocks the seal and the liquid portion from each other. In some embodiments, the first shield extends from the conductor by a distance that is greater than or equal to about 1.5 times the width of the conductor. In some embodiments, the first shield is shaped to increase an effective gas diffusion path from the liquid portion to the seal by greater than or equal to about 10% relative to the same high temperature device without the shield. In some embodiments, the first shield is shaped to provide about 7cm^-1Or more effective gas diffusion paths from the liquid portion to the seal.

In some embodiments, the first shield is shaped to increase the effective ion path length from the liquid portion to the seal by about 30% or more relative to an otherwise identical high temperature device without a shield. In some embodiments, the increase in effective ion diffusion path length is about 75% or more. In some embodiments, the first shield is shaped to provide an effective ion diffusion path length of greater than or equal to about 1.5. In some embodiments, the first shield is shaped to provide an effective ion diffusion path length of greater than or equal to about 2.

In some embodiments, the conductor is a negative current lead. In some embodiments, the device further comprises a second shield disposed between the first shield and the seal. In some embodiments, the first and second shields include alternating raised and recessed portions shaped to create a diffusion path from the liquid portion to the seal having a length that is at least 1.5 times the width of the container. In some embodiments, the second shield is coupled to a wall of the chamber. In some embodiments, the first shield is in electrical contact with the negative current lead, and wherein the second shield is in electrical contact with the positive current lead.

In some embodiments, the device further comprises a second shield in electrical contact with the positive current lead and disposed between the first shield and the liquid portion. In some embodiments, the liquid portion produces a vapor, and the second shield converts the vapor to salt upon contact. In some embodiments, an interior surface of the container exposed to the gaseous portion comprises an ion-conducting membrane in electrical communication with a positive current source, and the first shield is shaped such that vapor flowing between the liquid portion and the seal flows along the interior surface. In some embodiments, the first shield includes a rim at a perimeter thereof shaped and positioned in the chamber to inhibit capillary flow of liquid from the liquid portion along a path from the liquid portion to the seal.

In one aspect, the present disclosure provides an electrochemical cell comprising: a vessel having a chamber containing a reactive material maintained at a temperature of at least about 200 ℃; a seal sealing the chamber of the vessel from an environment external to the vessel, wherein the seal comprises a ceramic component exposed to the reactive material and a metal sleeve coupled to the ceramic component by a braze; and a current lead extending from the external environment of the container to the chamber of the container, wherein current lead is in electrical contact with the reactive material, and wherein the current lead includes a shoulder comprising the same material as the current lead, and wherein shoulder couples the sleeve to the current lead.

In some embodiments, the current lead is a negative current lead. In some embodiments, the electrochemical cell further includes a negative current collector within the chamber and attached to one end of the negative current lead. In some embodiments, the negative current lead includes a cylindrical body extending through the seal and a threaded portion attaching the negative current lead to the negative current collector, and the negative current lead further includes two parallel, substantially flat surfaces on opposite sides of an end of the negative current lead outside of the container. In some embodiments, the negative electrode current collector comprises a foam.

In some embodiments, the high temperature device is a battery, and wherein the battery comprises a negative electrode, a positive electrode, and a liquid electrolyte. In some embodiments, at least one of the negative electrode and the positive electrode is a liquid metal electrode. In some embodiments, the liquid electrolyte is a molten halide electrolyte.

Additional aspects and advantages of the present disclosure will become readily apparent to those skilled in this art from the following detailed description, wherein only illustrative embodiments of the present disclosure are shown and described. As will be realized, the disclosure is capable of other and different embodiments and its several details are capable of modifications in various, readily understood aspects all without departing from the disclosure. Accordingly, the drawings and description are to be regarded as illustrative in nature, and not as restrictive.

Disclosure of Invention

All publications, patents, and patent applications mentioned in this specification are herein incorporated by reference to the same extent as if each individual publication, patent, or patent application was specifically and individually indicated to be incorporated by reference.

Drawings

The novel features of the invention are set forth with particularity in the appended claims. A better understanding of the features and advantages of the present invention will be obtained by reference to the following detailed description that sets forth illustrative embodiments, in which the principles of the invention are utilized, and the accompanying drawings (also referred to herein as "the drawings" or "the figures"), of which:

fig. 1 is a schematic diagram of a grouping (e.g., a battery) of electrochemical cells (a) and electrochemical cells (B and C);

FIG. 2 is a schematic cross-sectional view of a housing having a conductor in electrical communication with a current collector through an aperture in the housing;

FIG. 3 illustrates a seal design having a ceramic component disposed between one or more metal sleeves;

FIG. 4 illustrates an electrochemical cell containing reactive materials and including a seal including additional components to inhibit corrosion of the seal;

FIG. 5 illustrates an electrochemical cell having a shield configured to increase the effective gas diffusion path;

FIG. 6 illustrates an electrochemical cell having a plurality of shrouds configured to further increase the diffusion path length;

FIG. 7 illustrates an electrochemical cell having a shroud with a lip to inhibit the flow and splashing of liquid toward a seal;

figure 8 illustrates an electrochemical cell having a shield configured to increase the effective ion diffusion path;

FIG. 9 is an image of a cell having a positive polarized shield disposed between a liquid portion and a negative polarized shield;

10A, 10B and 10C illustrate different configurations of physical ion blockers;

FIG. 11A illustrates a negative current lead including a Negative Current Lead (NCL) coupler;

FIG. 11B shows front and side views of a current lead including a pair of substantially flat parallel surfaces at one end;

FIG. 12 shows a schematic depiction of a brazed ceramic seal in which the material is thermodynamically stable with respect to the internal and external environments of the cell;

FIG. 13 illustrates a seal in which the ceramic material and/or the braze material are not thermodynamically stable with respect to the internal and external environments;

FIG. 14 shows an example of a brazed ceramic seal;

FIG. 15 shows an example of a brazed ceramic seal;

FIG. 16 shows an example of a brazed ceramic seal; and

FIG. 17 shows an example of a brazed ceramic seal;

Detailed Description

While various embodiments of the present invention have been shown and described herein, it will be readily understood by those skilled in the art that such embodiments are provided by way of example only. Numerous variations, changes, and substitutions will now occur to those skilled in the art without departing from the invention. It should be understood that various alternatives to the embodiments of the invention described herein may be employed. It is to be understood that the different aspects of the invention may be understood individually, collectively, or in combination with each other.

As used herein, the term "metal-to-metal direct bond" or "metal-to-metal direct bond" generally refers to an electrical connection that brings two metal surfaces into contact (e.g., by forming a solder joint or pad). In some examples, the metal-to-metal direct bond does not include a wire.

The term "electronically" as used herein generally refers to the situation in which electrons can readily flow between two or more components having a relatively small resistance. Components that are in electronic communication with each other may be in electrical communication with each other.

The term "perpendicular" as used herein generally refers to a direction parallel to the direction of gravity.

The term "stable" as used herein to describe a material generally refers to a material that is thermodynamically stable, chemically stable, thermochemically stable, electrochemically stable, kinetically stable, or any combination thereof. A stable material may be substantially thermodynamically, chemically, thermochemically, electrochemically, and/or kinetically stable. The stabilized material may be substantially chemically or electrochemically non-reducible, non-corrosive or non-corrosive. Any aspect described in this disclosure with respect to a stable, thermodynamically stable, or chemically stable material may equally apply, at least in some configurations, to thermodynamically stable, chemically stable, thermochemically stable, and/or electrochemically stable materials.

Ceramic material and seal for high temperature devices

The present disclosure provides a seal or corrosion resistant liner for a high temperature device. The device may be a high temperature reactive material device containing/comprising one or more reactive materials. For example, the high temperature device may contain a reactive material. In some cases, the device may be a high temperature reactive metal device. The apparatus may be used, but is not limited to, for production and/or processing of reactive materials such as, for example, reactive metals (e.g., lithium, sodium, magnesium, aluminum, calcium, titanium, and/or other reactive metals) and/or chemicals with strong chemical reduction capabilities (e.g., reactive chemicals), for semiconductor manufacturing, for nuclear reactors (e.g., nuclear fusion/fission reactors, nuclear reactors using molten salts or metals such as, for example, molten sodium or lithium or molten sodium-or lithium-containing alloys as coolants), for heterogeneous reactors, for chemical processing plants, for chemical transportation plants, for chemical storage plants, or for batteries (e.g., liquid metal batteries). For example, some batteries operate at high temperatures (e.g., at least about 100 ℃ or 300 ℃) and have reactive metal vapors (e.g., vapors of lithium, sodium, magnesium, aluminum, or calcium, etc.) that can be sufficiently contained within the battery to reduce failure. In some examples, such high temperature devices operate, are heated to, and/or are maintained at: at least about 100 ℃, 150 ℃,200 ℃, 250 ℃, 300 ℃, 350 ℃, 400 ℃, 450 ℃,500 ℃, 550 ℃, 600 ℃, 650 ℃, 700 ℃, 750 ℃, 800 ℃, 850 ℃, 900 ℃ or higher temperature. At such temperatures, one or more components of the device may be in a liquid (or molten) or vapor state.

The device may comprise a ceramic material. Ceramic materials may be used as dielectric insulators in devices containing one or more reactive materials. The apparatus may be operated at a temperature of, for example, at least about 300 ℃ or 400 ℃. The apparatus may be associated with a nuclear fission or fusion reactor. The dielectric insulator may be part of a seal (e.g., a hermetic seal). The ceramic material may be used in a seal for a device containing a reactive material and operated at a temperature greater than about 300 ℃.

The seal may comprise a ceramic material (e.g. aluminum nitride (AlN)) in contact with a reactive material (e.g. a reactive metal or molten salt) contained in the apparatus. The ceramic material may be capable of being chemically resistant to a reactive material (e.g., a reactive material contained in the device, such as a reactive metal or molten salt, for example). The ceramic material may be capable of being chemically resistant to the reactive material when the device is operated at high temperatures (e.g., at least about 100 ℃, 150 ℃,200 ℃, 250 ℃, 300 ℃, 350 ℃, 400 ℃,500 ℃, 600 ℃, 700 ℃, 800 ℃, or 900 ℃).

The seal may comprise an active metal braze joint disposed between the ceramic material and at least one of the metal collar/sleeve and the device. The active metal braze joint may include a metal species that chemically reduces the ceramic material (e.g., titanium (Ti) or zirconium (Zr)).

The seal may surround an electrically conductive feedthrough (and may electrically isolate the feedthrough from the housing of the device), a thermocouple, or a voltage sensor. For example, the ceramic material may be an insulator.

In some examples, the seal may be capable of being chemically resistant to the reactive material in the device at a temperature of at least about 100 ℃, 150 ℃,200 ℃, 250 ℃, 300 ℃, 350 ℃, 400 ℃,500 ℃, 600 ℃, 700 ℃, 800 ℃, or 900 ℃. In some examples, the seal may be capable of being chemically resistant to the reactive material at such temperatures for a period of at least about 6 months, 1 year, 2 years, 5 years, 10 years, 20 years, or more. In some examples, the device may be a high temperature reactive metal device, and the seal may be capable of being chemically resistant to a material in the device containing the reactive metal. In one example, the seal is capable of withstanding lithium vapor at a temperature of at least about 300 ℃ for at least about one year. The seal can retain a reactive material (e.g., a vapor of the reactive material) in the device. For example, the seal may retain reactive metal vapors and/or molten salt vapors in the device.

Electrochemical cell, device and system

The present disclosure provides electrochemical energy storage devices (e.g., batteries) and systems. The energy storage device may be formed or provided within the energy storage system. Electrochemical energy storage devices typically include at least one electrochemical cell, also referred to herein as a "cell" and a "battery cell," sealed (e.g., hermetically sealed) within a housing. The cells may be configured to deliver electrical energy (e.g., electrons at an electrical potential) to a load, such as, for example, an electronic device, another energy storage device, or an electrical grid.

An electrochemical cell of the present disclosure may include a negative electrode, an electrolyte adjacent to the negative electrode, and a positive electrode adjacent to the electrolyte. The negative electrode and the positive electrode may be separated by an electrolyte. The negative electrode may be an anode during discharge. The positive electrode may be a cathode during discharge. The cell may include a negative electrode made of material 'a' and a positive electrode made of material 'B', denoted as a | | B. The positive electrode and the negative electrode may be separated by an electrolyte. The monolith may also include a housing, one or more current collectors, and a seal (e.g., a high temperature electrical isolation seal).

In some examples, the electrochemical cell is a liquid metal battery cell. In some examples, a liquid metal battery cell may include a liquid electrolyte disposed between a liquid (e.g., molten) metal negative electrode and a solid, semi-solid, liquid (e.g., molten) metal, metalloid, and/or nonmetal positive electrode. In some cases, a liquid metal battery cell has a molten alkaline earth metal (e.g., magnesium (Mg), calcium (Ca)) or alkali metal (e.g., lithium, sodium, potassium) negative electrode, an electrolyte, and a molten metal positive electrode. The molten metallic positive electrode may include, for example, one or more of tin (Sn), lead (Pb), bismuth (Bi), antimony (Sb), tellurium (Te), and selenium (Se). For example, the positive electrode may include liquid Pb, solid Sb, a liquid or semi-solid Pb-Sb alloy, or liquid Bi. The positive electrode can also include one or more transition metals or d-block elements (e.g., zinc (Zn), cadmium (Cd), and mercury (Hg)), such as, for example, a Zn-Sn alloy or a Cd-Sn alloy, alone or in combination with other metals, metalloids, or nonmetals. In some examples, the positive electrode can include a metal or metalloid having one stable oxidation state (e.g., a metal having a single or single oxidation state). Any description herein of a metallic or molten metal positive electrode, or any description of a positive electrode, may refer to an electrode comprising one or more of a metal, a metalloid, and a nonmetal. The positive electrode may comprise one or more of the listed examples of materials. In one example, the positive metal electrode can include lead and/or antimony. In some examples, the metal positive electrode can include an alkali metal and/or an alkaline earth metal alloyed in the positive electrode.

The electrolyte may include a salt (e.g., a molten salt) such as an alkali metal salt or an alkaline earth metal salt. The alkali or alkaline earth metal salt may be a halide, such as a fluoride (F), chloride (Cl), bromide (Br), or iodide (I) of an active alkali or alkaline earth metal, or a combination thereof. In one example, the electrolyte (e.g., in a type 1 or type 2 chemical process) includes lithium chloride (LiCl). In some examples, the electrolyte may include sodium fluoride (NaF), sodium chloride (NaCl), sodium bromide (NaBr), sodium iodide (NaI), lithium fluoride (LiF), lithium chloride (LiCl), lithium bromide (LiBr), lithium iodide (LiI), potassium fluoride (KF), potassium chloride (KCl), potassium bromide (KBr), potassium iodide (KI), calcium fluoride (CaF)₂) Calcium chloride (CaCl)₂) Calcium bromide (CaBr)₂) Calcium iodide (CaI)₂) Strontium fluoride (SrF)₂) Strontium chloride (SrCl)₂) Strontium bromide (SrBr)₂) Strontium iodide (SrI)₂) Or any combination thereof. In some examples, the electrolyte includes magnesium chloride (MgCl)₂). Alternatively, the salt of the active alkali metal may be, for example, a non-chlorine halide, a bisimide salt, a fluorosulfonyl-amine salt, a perchlorate, a hexafluorophosphate, a tetrafluoroborate, a carbonate, a hydroxide, a nitrate, a nitrite, a sulfate, sulfurous acidA salt, or a combination thereof. In some cases, the electrolyte can include a mixture of salts (e.g., 25:55:20 mol-% LiF: LiCl: LiBr, 50:37:14 mol-% LiCl: LiF: LiBr, 34:32.5:33.5 mol-% LiCl-LiBr-KBr, etc.). In some examples, the electrolyte comprises about 30:15:55 mol% CaCl₂KCl and LiCl. In some examples, the electrolyte comprises about 35:65 mol% CaCl₂LiCl. In some examples, the electrolyte comprises about 24:38:39 wt% LiCl: CaCl₂:SrCl₂. In some examples, the electrolyte comprises at least about 20 wt% CaCl₂20 wt% SrCl₂And 10 wt% KCl. In some examples, the electrolyte comprises at least about 10 wt% LiCl, 30 wt% CaCl₂30 wt% SrCl₂And 10 wt% KCl. The electrolyte may exhibit low (e.g., minimal) electronic conductivity. For example, the electrolyte may have an electron transport number (i.e., the percentage of charge (electrons and ions) due to the transport of electrons) of less than or equal to about 0.03% or 0.3%.

In some cases, the negative electrode and/or the positive electrode of the electrochemical energy storage device is in a liquid state at an operating temperature of the energy storage device. To maintain the electrode(s) in the liquid state(s), the battery cell may be heated to any suitable temperature. In some examples, the battery cell is heated to and/or maintained at a temperature of about 100 ℃, 150 ℃,200 ℃, 250 ℃, 300 ℃, 350 ℃, 400 ℃, 450 ℃, 475 ℃,500 ℃, 550 ℃, 600 ℃, 650 ℃, or about 700 ℃. The battery cell may be heated to and/or maintained at a temperature of at least about 100 ℃, 150 ℃,200 ℃, 250 ℃, 300 ℃, 350 ℃, 400 ℃, 450 ℃, 475 ℃,500 ℃, 550 ℃, 600 ℃, 650 ℃, 700 ℃, 800 ℃ or 900 ℃. In such cases, the negative electrode, electrolyte, and/or positive electrode may be in a liquid (or molten) state. In one example, the negative electrode and electrolyte are in a liquid state, and the positive electrode is in a solid or semi-solid state. In some cases, the battery cell is heated to between about 200 ℃ to 600 ℃,500 ℃ to 550 ℃, or 450 ℃ to 575 ℃.

In some embodiments, the electrochemical cell or the energy storage device may be at least partially or fully self-heating. For example, the cell may be sufficiently insulated, charged, discharged, and/or under conditions of sufficient rate, and/or cycled for a sufficient percentage of time to allow the system to generate sufficient heat through inefficiencies in cycling operation such that the monomer is maintained at a given operating temperature (e.g., a monomer operating temperature above the freezing point of at least one of the liquid components) without the need to apply additional energy to the system.

The electrochemical cells of the present disclosure may be adapted to cycle between a charging (or energy storage) mode and a discharging mode. In some examples, the electrochemical cells may be fully charged, partially charged, or partially discharged or fully discharged.

The monomer may have a voltage. The Charge Cutoff Voltage (CCV) may refer to a voltage at which the cell is fully charged or substantially fully charged, such as the voltage cutoff limit used in a battery when cycling in constant current mode. The Open Circuit Voltage (OCV) may refer to the voltage of the cell (e.g., fully or partially charged) when the cell is disconnected from any electrical circuit or external load (i.e., when no current is flowing through the cell). As used herein, voltage or cell voltage may refer to the voltage of a cell (e.g., in any of a charging condition or a charging/discharging condition). In some cases, the voltage or cell voltage may be an open circuit voltage. In some cases, the voltage or cell voltage may be a voltage during charging or during discharging. The voltages of the present disclosure may be employed or expressed relative to a reference voltage, such as a ground voltage (0 volts (V)) or the voltage of the opposite electrode in the electrochemical cell.

The present disclosure provides cells of type 1 and type 2 that may vary based on and defined by the composition of the active components (e.g., negative electrode, electrolyte, and positive electrode), and may vary based on the mode of operation of the cell (e.g., low voltage mode versus high voltage mode). The monomer may include a material configured for use in a type 2 mode of operation. The monomer may include a material configured for use in a type 1 mode of operation. In some cases, the cells may operate in both a high voltage (type 2) mode of operation and a low voltage (type 1) mode of operation. For example, a cell having a positive electrode material and a negative electrode material generally configured for use in a type 1 mode may be operated in a type 2 mode of operation. The monomer may be cycled between a type 1 mode of operation and a type 2 mode of operation. The monomer may be initially charged (or discharged) to a given voltage (e.g., 0.5V to 1V) in the type 1 mode, and then charged (and then discharged) to a higher voltage (e.g., 1.5V to 2.5V or 1.5V to 3V) in the type 2 mode. In some cases, the cell operating in the type 2 mode may be operated at a voltage between the electrodes that may exceed the voltage of the cell operating in the type 1 mode. In some cases, the type 2 monomer chemistry may be operated at a voltage between the electrodes that may exceed the voltage of the type 1 monomer chemistry operating in the type 1 mode. The type 2 monomer may be operated in a type 2 mode.

In one example of a type 1 monomer, cations formed at the negative electrode upon discharge can migrate into the electrolyte. At the same time, the electrolyte can provide the positive electrode with the same kind of cations (e.g., cations of the negative electrode material) (e.g., Sb, Pb, Bi, Sn, or any combination thereof), which can reduce the cations to uncharged metal species and undergo an alloying reaction with the positive electrode. In some examples, different cationic species in the electrolyte may co-deposit onto the positive electrode (e.g., calcium)²⁺(Ca²⁺) And lithium⁺(Li⁺) Deposit onto Sb and form Ca-Li-Sb alloy(s). In the discharged state, the negative electrode of the negative electrode material (e.g., lithium (Li), sodium (Na), potassium (K), Mg, Ca) may be depleted (e.g., partially or fully). During charging, the alloy on the positive electrode can decompose to produce one or more different kinds of cations (e.g., Li) of the negative electrode material that migrate into the electrolyte⁺、Na⁺、K⁺、Mg²⁺、Ca²⁺). The electrolyte may then provide cations (e.g., cations of the negative electrode material) to the negative electrode, where the cations accept one or more electrons from an external circuit and convert back to neutral metal species, whichThe negative electrode is recharged to provide the cell in a charged state. In some examples, different cationic species in the electrolyte may co-deposit onto the negative electrode during charging. Type 1 monomers can operate in a ballistic manner in which entry of one or a group of cations into the electrolyte results in release of the same cation or a group of cation species from the electrolyte.

In one example of a type 2 cell, the electrolyte contains cations of the negative electrode material (e.g., Li) in the discharged state⁺、Na⁺、K⁺、Mg²⁺、Ca²⁺) And the positive electrode includes a positive electrode material (e.g., Sb, Pb, Sn, Zn, Hg). During discharge, cations from the negative electrode material of the electrolyte accept one or more electrons (e.g., from a negative current collector) to form a negative electrode comprising the negative electrode material. In some examples, the negative electrode material is a liquid and wets into the foam (or porous) structure of the negative current collector. In some examples, the negative current collector may not include a foam (or porous) structure. In some examples, the negative current collector may include a metal, such as, for example, tungsten (W) (e.g., to avoid corrosion by Zn), tungsten carbide (WC), or molybdenum (Mo) that does not include iron-nickel (Fe-Ni) foam. At the same time, the positive electrode material from the positive electrode gives off electrons (e.g., to a positive current collector) and dissolves into the electrolyte as cations of the positive electrode material (e.g., Sb)³⁺、Pb²⁺、Sn²⁺、Zn²⁺、Hg²⁺). The concentration of cations of the positive electrode material can vary with vertical proximity within the electrolyte (e.g., as a function of distance over the positive electrode material) based on the atomic weight and diffusion kinetics of the cationic material in the electrolyte. In some examples, cations of the positive electrode material are enriched in the electrolyte near the positive electrode.

In some embodiments, the negative electrode material may not be provided when assembling a cell operable in the type 2 mode. For example, Li Pb monomers or energy storage devices including such monomer(s) may be assembled in a discharged state with a Li salt electrolyte and a Pb or Pb alloy (e.g., Pb-Sb) positive electrode (i.e., Li metal may not be included during assembly).

While the electrochemical cell of the present disclosure has been described, in some examples, when operating in either type 1 mode or type 2 mode, other modes of operation are possible. The type 1 mode or the type 2 mode is provided as an example and is not intended to limit the various modes of operation of the electrochemical cells disclosed herein.

In some cases, electrochemical cells include liquid metal negative electrodes (e.g., sodium (Na) or lithium (Li)), liquid (e.g., LiF — LiCl-LiBr, LiCl-KCl, or LiCl-LiBr-KBr) or solid ion conducting electrolytes (e.g., β "-alumina ceramics), and solid, liquid, or semi-solid positive electrodes (e.g., solid matrices or particle beds impregnated with liquid or molten electrolytes). Such a cell may be a high temperature battery. One or more such monomers may be provided in an electrochemical energy storage device. The negative electrode may comprise an alkali metal or alkaline earth metal such as, for example, lithium, sodium, potassium, magnesium, calcium, or any combination thereof. The positive electrode and/or electrolyte may include a liquid chalcogen or a molten chalcogen-halogen compound (e.g., elemental, ionic, or other form of sulfur (S), selenium (Se), or tellurium (Te)), the molten salt including a transition metal halide (e.g., a halide comprising Ni, Fe, chromium (Cr), manganese (Mn), cobalt (Co), or vanadium (V), such as, for example, nickel chloride (NiCl)₃) Or ferric chloride (FeCl)₃) Solid transition metals (e.g., particles of Ni, Fe, Cr, Mn, Co, or V), sulfur, one or more metal sulfides (e.g., FeS)₂、FeS、NiS₂、CoS₂Or any combination thereof), liquid or molten alkali metal halo-metal salts (e.g., including aluminum (Al), Zn, or Sn) and/or other (e.g., supporting) compounds (e.g., NaCl, NaF, NaBr, NaI, KCl, LiCl, or other alkali metal halides, bromide salts, elemental zinc, zinc-chalcogen or zinc-halogen compounds, or metal main group metal or oxygen scavengers such as, for example, aluminum or transition metal-aluminum alloys), or any combination thereof. The solid ion-conducting electrolyte may comprise beta alumina (e.g., beta "-oxygen) capable of conducting sodium ions at elevated or high temperaturesAluminum oxide) ceramic. In some cases, the solid ion-conducting electrolyte operates above about 100 ℃, 150 ℃,200 ℃, 250 ℃, 300 ℃, or 350 ℃.

In one example, an electrochemical cell in a charged state includes a negative electrode comprising calcium, and a negative electrode comprising CaCl₂And an antimony-containing positive electrode. The working temperature of the monomer may be less than about 600 deg.C, 550 deg.C, 500 deg.C, 450 deg.C, 400 deg.C, 350 deg.C, 300 deg.C, 250 deg.C or 200 deg.C. In some examples, the monomer can have an operating temperature of at least about 200 ℃, 250 ℃, 300 ℃, 350 ℃, 400 ℃, 450 ℃,500 ℃ or more. The positive electrode or cathode in the charged state may contain solid antimony and/or solid antimony alloys, and may not contain any liquid metal. The negative electrode or anode in the charged state may comprise lithium and/or magnesium metal. The negative electrode may remain in a liquid or semi-solid state under normal operating (e.g., charging, discharging) conditions.

Any aspect of the disclosure described with respect to the cathode may be equally applicable to the anode, at least in some configurations. Similarly, one or more of the cell electrodes and/or electrolyte may not be liquid in alternative configurations. In further examples, at least one battery electrode may be a solid, gel, or paste. Further, in some examples, the electrodes and/or electrolyte may not contain a metal. Aspects of the present disclosure are applicable to various energy storage/conversion devices and are not limited to liquid metal batteries.

Battery and housing

The electrochemical cells of the present disclosure may include a housing that may be suitable for various uses and operations. The housing may comprise one single body or a plurality of single bodies. The housing may be configured to electrically couple the electrode to a switch, which may be connected to an external power source and an electrical load. The cell housing can, for example, include a conductive current feed-through conductor (e.g., a current lead bar) electrically coupled to a first pole of the switch and/or another cell housing, and a conductive container lid electrically coupled to a second pole of the switch and/or another cell housing. The monomer may be disposed within a cavity of the container. A first of the electrodes of the cell (e.g., the positive electrode) may contact and be electrically coupled with an end wall of the container. A second of the electrodes (e.g., a negative electrode) of the cells may contact and be electrically coupled to a conductive feedthrough or conductor (e.g., a negative current lead) on a container lid (collectively referred to herein as a "cell lid assembly," "lid assembly," or "cap assembly"). An electrically insulating seal (e.g., a bonded ceramic ring) can electrically isolate the negative potential portion of the cells from the positive portions of the cells (e.g., electrically isolate the negative current lead from the positive current lead or electrically isolate the positive polarized current lead from the negative polarized cell cover/cell casing). In one example, the negative current lead and the container lid (e.g., cell cap) can be electrically isolated from each other, wherein a dielectric sealant material can be placed between the negative current lead and the cell cap. Alternatively, the housing comprises an electrically insulating sheath (e.g., an alumina sheath) or a corrosion resistant and electrically conductive sheath or crucible (e.g., a graphite sheath or crucible). In some examples, the housing and/or container may be a battery housing and/or container.

The monomer can have any of the monomer and seal configurations disclosed herein. For example, the reactive monomer material may be held within a sealed steel/stainless steel container with a high temperature seal on the monomer lid. A current lead (e.g., a negative current lead rod) may be passed through the cell cover (and sealed thereto by a dielectric high temperature seal) and connected with a porous current collector (e.g., a negative current collector, such as metal foam) suspended in an electrolyte. In some examples, the monomer may use a graphite sheath, coating, crucible, surface coating, or lining (or any combination thereof) on the inner wall of the monomer crucible (e.g., container). In some examples, the monomer may not use a graphite sheath, coating, crucible, surface coating, or lining on the inner wall of the monomer crucible (e.g., container).

The monomers may have a set of sizes. In some examples, the monomer may be greater than or equal to about 4 inches wide, 4 inches deep, and 2.5 inches high. In some examples, the monomer may be greater than or equal to about 8 inches wide, 8 inches deep, and 2.5 inches high. In some examples, the height and width of the cells may be greater than the depth of the cells, and may be referred to as a "prismatic" cell geometry, with the seal located on the top horizontal surface of the cell. The prismatic cell geometry may be at least about 4 inches, 6 inches, 8 inches, 10 inches, 12 inches, 14 inches, or more in width, at least about 4 inches, 6 inches, 8 inches, 10 inches, 12 inches, 14 inches, or more in height, and less than about 8 inches, 6 inches, 4 inches, 2 inches, or less in depth. In some examples, the prismatic cell geometry has a width of about 4 inches, a height of about 6 inches, and a depth of about 2 inches. In some examples, the prismatic cell geometry has a width of about 6 inches, a height of about 6 inches, and a depth of about 2 inches. In some examples, the prismatic cell geometry has a width of about 6 inches, a height of about 6 inches, and a depth of about 3 inches. In some examples, the prismatic cell geometry has a width of about 8 inches, a height of about 8 inches, and a depth of about 2 inches. In some examples, the prismatic cell geometry has a width of about 8 inches, a height of about 8 inches, and a depth of about 3 inches. In some examples, the prismatic cell geometry has a width of about 9 inches, a height of about 9 inches, and a depth of about 2 inches. In some examples, the prismatic cell geometry has a width of about 9 inches, a height of about 9 inches, and a depth of about 3 inches. In some examples, any given dimension (e.g., height, width, or depth) of the electrochemical cell may be at least about 1 inch, 2 inches, 2.5 inches, 3 inches, 3.5 inches, 4 inches, 4.5 inches, 5 inches, 5.5 inches, 6 inches, 6.5 inches, 7 inches, 7.5 inches, 8 inches, 8.5 inches, 9 inches, 9.5 inches, 10 inches, 12 inches, 14 inches, 16 inches, 18 inches, or 20 inches. In one example, the cells (e.g., each cell) can have dimensions greater than or equal to about 4 inches by 2 inches. In some examples, the cells (e.g., each cell) may have dimensions greater than or equal to about 8 inches by 2.5 inches. In some examples, the cells may have an energy storage capacity of greater than or equal to about 50 watt-hours. In some examples, the battery may have an energy storage capacity of at least about 200 watt-hours.

The positive electrode can be in electrical communication with a positive current collector. In some embodiments, the positive electrode can be in electrical communication with the housing. In some embodiments, the positive electrode can comprise antimony. In some embodiments, the positive electrode can comprise an antimony alloy. In some embodiments, the positive electrode can be a solid metal electrode. In some embodiments, the solid metal positive electrode can be a flat plate configuration. Alternatively or additionally, the solid metal positive electrode may contain particles. The particles may comprise particles, flakes, needles, or any combination thereof of solid materials. In some embodiments, the positive electrode can be solid antimony. The solid antimony may be of a flat sheet construction. Alternatively or additionally, the solid antimony may be particles comprising particles, flakes, needles, or any combination thereof of a solid material. The solid metallic positive electrode particles can include a size of at least about 0.001mm, at least about 0.01mm, at least about 0.1mm, at least about 0.25mm, at least about 0.5mm, at least about 1mm, at least about 2mm, at least about 3mm, at least about 5mm, or more. In some embodiments, the electrolyte is located on top of the positive electrode. Alternatively or additionally, the positive electrode may be immersed in or surrounded by the electrolyte.

The electrochemical cells can be arranged within the housing such that the mean flow path of the ions is substantially perpendicular to the plane of the container lid (e.g., when the lid is facing up, the ions flow vertically between the negative electrode and the positive electrode). The configuration may include a negative electrode included within a negative current collector suspended within the cavity of the case by a negative current lead. In this configuration, the width of the negative electrode current collector may be greater than the height. The negative electrode may be partially or fully immersed in the molten salt electrolyte. A gaseous headspace may exist above the negative electrode (i.e., between the negative electrode and the container lid). The molten salt electrolyte may be between and separate the negative electrode and the positive electrode. The positive electrode can be located at or near the bottom of the cavity (i.e., opposite the container lid). The positive electrode may comprise a solid slab geometry or may comprise particles of a solid material. The positive electrode may be located below the electrolyte, or may be submerged or surrounded by the electrolyte. During discharge, ions can flow from the negative electrode to the positive electrode with an average flow path perpendicular to and away from the container lid. During charging, ions can flow from the positive electrode to the negative electrode with an average flow path perpendicular to and towards the container lid.

The electrochemical cells can be arranged with the housing such that the mean flow path of the ions is substantially parallel to the plane of the container lid (e.g., when the lid is facing up, the ions flow horizontally between the negative electrode and the positive electrode). In some examples, the electrochemical cell includes a negative electrode included within a negative current collector suspended within the cavity of the case by a negative current lead. In this configuration, the height of the negative electrode current collector may be greater than the width. The negative electrode may be partially or fully immersed in the molten salt electrolyte. A gaseous headspace may exist between the negative electrode and the container lid. In some embodiments, the negative electrode may be submerged and covered with molten electrolyte, and the gaseous headspace may be between the electrolyte and the container lid. The positive electrode can be positioned along the side wall of the housing between the bottom of the cavity and the container lid. The positive electrode may be positioned along a portion of the inner side wall or cover one or more of the entire inner side wall of the cavity. The positive electrode can cover an area that is at least about 5%, at least about 10%, at least about 20%, at least about 30%, at least about 40%, at least about 50%, at least about 60%, at least about 70%, at least about 80%, at least about 90% or more of the side wall.

The cross-sectional geometry of the cell or battery may be circular, oval, square, rectangular, polygonal, curved, symmetrical, asymmetrical, or any other composite shape based on the design requirements of the battery. In some examples, the cells or cells are axially symmetric, having a circular or square cross-section. The cells or components of the battery (e.g., the negative electrode current collector) can be arranged within the cells or battery in an axisymmetric manner. In some cases, one or more components may be arranged asymmetrically, such as, for example, off-center from an axis.

One or more electrochemical cells ("cells") may be arranged in groups. Examples of electrochemical cell sets include modules, packaging packs, cores, CEs, and systems.

A module may include cells attached together in parallel (e.g., cells connected together in a generally horizontal packaging plane), for example, by mechanically connecting the cell housings of one cell with the cell housings of an adjacent cell. In some examples, a module may include cells attached together in series by, for example, mechanically connecting the cell housings of one cell with current lead bars protruding from the seals of an adjacent cell. In some examples, the cells are connected to each other by an engagement feature that is part of and/or connected to the cell body (e.g., a tab protruding from a major portion of the cell body). A module may comprise a plurality of cells in parallel or in series. A module may include any number of monomers, for example, at least about 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, or more monomers. In some examples, a module contains at least about 4, 9, 12, or 16 monomers. In some examples, the module is capable of storing energy greater than or equal to about 700 watt-hours and/or delivering at least about 175 watts of power. In some examples, the module is capable of storing at least about 1080 watt-hours of energy and/or delivering at least about 500 watts of power. In some examples, the module is capable of storing at least about 1080 watt-hours of energy and/or delivering at least about 200 watts (e.g., greater than or equal to about 500 watts) of power. In some examples, a module may include a single cell.

The package may include modules attached by different electrical connections (e.g., vertically). The encapsulation package may include any number of modules, for example, at least about 1,2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, or more modules. In some examples, the encapsulation package includes at least about 3 modules. In some examples, one package can store at least about 2 kilowatt-hours of energy and/or deliver at least about 0.4 kilowatts (e.g., at least about 0.5 kilowatts or 1.0 kilowatts) of power. In some examples, one package can store at least about 3 kilowatt-hours of energy and/or deliver at least about 0.75 kilowatts (e.g., at least about 1.5 kilowatts) of power. In some examples, the encapsulation package includes at least about 6 modules. In some examples, the encapsulation package is capable of storing energy greater than or equal to about 6 kilowatt-hours and/or delivering at least about 1.5 kilowatts of power (e.g., greater than or equal to about 3 kilowatts). In some examples, the modules are connected together in a series connection into one package.

The core may comprise a plurality of modules or packages attached by different electrical connections (e.g., by series and/or parallel). The core may comprise any number of modules or packages, for example, at least about 1,2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 45, 50 or more packages. In some examples, the core further includes mechanical, electrical, and thermal systems that allow the core to efficiently store and return electrical energy in a controlled manner. In some examples, the core includes at least about 12 encapsulated packets. In some examples, the core is capable of storing at least about 25 kilowatt-hours of energy and/or delivering at least about 6.25 kilowatts of power. In some examples, the core includes at least about 36 encapsulated packets. In some examples, the core is capable of storing energy of at least about 200 kilowatt-hours and/or delivering at least about 40, 50, 60, 70, 80, 90, 100, 200, 500, 1000 kilowatts or more of power.

A "core enclosure" (CE) may include multiple cores attached by different electrical connections (e.g., by series and/or parallel). The CE may include any number of cores, for example, at least about 1,2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20 or more cores. In some examples, the CE contains cores connected in parallel with appropriate bypass electronic circuitry, enabling one core to be disconnected while continuing to allow the other core to store and return energy. In some examples, the CE includes at least 4 cores. In some examples, the CE is capable of storing at least about 100 kilowatt-hours of energy and/or delivering greater than or equal to about 25 kilowatts of power. In some examples, the CE includes 4 cores. In some cases, the CE is capable of storing about 100 kilowatt-hours of energy and/or delivering greater than or equal to about 25 kilowatts of power. In some examples, the CE is capable of storing energy greater than or equal to about 400 kilowatt-hours and/or delivering at least about 80 kilowatts of power, such as greater than or equal to about 80, 100, 120, 140, 160, 180, 200, 250, 300, 500, 1000 or more kilowatts or more of power.

A system may include multiple cores or CEs attached by different electrical connections (e.g., by series and/or parallel). The system may include any number of cores or CEs, for example, at least about 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20 or more cores. In some examples, the system includes 20 CEs. In some examples, the system is capable of storing energy greater than or equal to about 2 megawatt-hours (mega-Watt-hours) and/or delivering power of at least about 400 kilowatts (e.g., about or at least about 500 kilowatts or 1000 kilowatts). In some examples, the system includes 5 CEs. In some examples, the system is capable of storing energy greater than or equal to about 2 megawatts hours and/or delivering at least about 400 kilowatts of power, such as at least about 400, 500, 600, 700, 800, 900, 1,000, 1,200, 1,500, 2,000, 2,500, 3,000, or 5,000 kilowatts or more of power.

A single (e.g., core, CE, system, etc.) group having a given energy capacity and power capacity (e.g., a CE or system capable of storing a given amount of energy) may be configured to deliver a given (e.g., rated) power level of at least about 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, or 95%, or about 100%. For example, while a 1000kW system may also be capable of operating at 500kW, a 500kW system may not be capable of operating at 1000 kW. In some examples, a system having a given energy capacity and power capacity (e.g., a CE or system capable of storing a given amount of energy) may be configured to deliver a given (e.g., rated) power level of less than about 100%, 110%, 125%, 150%, 175%, or 200%, among others. For example, the system may be configured to provide more than its rated power capacity for a period of time that is less than the time it may take to consume its energy capacity at the power level being provided (e.g., provide more than the rated power of the system corresponding to less than about 1%, 10%, or 50% of its rated energy capacity for a period of time).

A battery may include one or more electrochemical cells connected in series and/or parallel. The battery may include any number of electrochemical cells, modules, packages, cores, CEs, or systems. The battery may undergo at least one charge/discharge or discharge/charge cycle ("cycle").

The battery may include one or more electrochemical cells. The monomer(s) may include a shell. The individual cells may be electrically coupled to each other in series and/or in parallel. In a series connection, the positive terminal of the first cell is connected to the negative terminal of the second cell. In a parallel connection, the positive terminal of the first cell may be connected to the positive terminal of the second cell and/or additional cell(s). Similarly, the cell modules, package, core, CE and system may be connected in series and/or parallel in the same manner as described for the cells.

Reference will now be made to the drawings, wherein like reference numerals refer to like parts throughout. It should be understood that the drawings and features therein are not necessarily drawn to scale.

Referring to fig. 1, an electrochemical cell (a) is a unit including an anode and a cathode. The monomer may include an electrolyte and be sealed in a housing as described herein. In some examples, electrochemical cells may be stacked (B) to form a battery (i.e., a grouping of one or more electrochemical cells). The monomers can be arranged in parallel, in series or both in parallel and in series (C). Further, as described in more detail elsewhere herein, the cells may be arranged into groups (e.g., modules, packages, cores, CEs, systems, or any other group comprising one or more electrochemical cells). In some examples, such a set of electrochemical monomers may allow for control or regulation of a given number of monomers together at a set level (e.g., in coordination with or in place of regulation/control of individual monomers).

The electrochemical cells in the present disclosure (e.g., type 1 cells operating in a type 2 mode, type 1 cells operating in a type 1 mode, or type 2 cells) may be capable of storing a suitably large amount of energy (e.g., a substantial amount of energy), accepting ("absorbing") input thereto, and/or releasing same. In some cases, the monomer is capable of storing, absorbing, and/or releasing greater than or equal to about 1 watt hour (Wh), 5Wh, 25Wh, 50Wh, 100Wh, 250Wh, 500Wh, 1 kWh (kWh), 1.5kWh, 2kWh, 3kWh, 5kWh, 10kWh, 15kWh, 20kWh, 30kWh, 40kWh, or 50 kWh. It should be appreciated that the amount of energy stored in the electrochemical cell and/or battery may be less than the amount of energy absorbed into the electrochemical cell and/or battery (e.g., due to inefficiencies and losses). The monomer may have such an energy storage capacity when operated at any of the current densities herein.

The monomer may be capable of at least about 10 milliamps per square centimeter (mA/cm)²)、20mA/cm²、30mA/cm²、40mA/cm²、50mA/cm²、60mA/cm²、70mA/cm²、80mA/cm²、90mA/cm²、100mA/cm²、200mA/cm²、300mA/cm²、400mA/cm²、500mA/cm²、600mA/cm²、700mA/cm²、800mA/cm²、900mA/cm²、1A/cm²、2A/cm²、3A/cm²、4A/cm²、5A/cm²Or 10A/cm²Wherein the current density is determined based on an effective cross-sectional area of the electrolyte and wherein the cross-sectional area is an area orthogonal to a net flow direction of ions through the electrolyte during a charging or discharging process. In some cases, the monomer may be capable of operating with a Direct Current (DC) efficiency of at least about 10%, 20%, 30%, 35%, 40%, 45%, 50%, 55%, 60%, 65%, 70%, 75%, 80%, 90%, 95%, etc. In some cases, the monomer may be capable of operating with a charge efficiency (e.g., Coulombic charge efficiency) of at least about 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 85%, 90%, 95%, 98%, 99%, 99.5%, 99.9%, 99.95%, 99.99%, etc.

In the charged state, an electrochemical cell of the present disclosure (e.g., a type 1 cell operating in a type 2 mode, a type 1 cell operating in a type 1 mode, or a type 2 cell) can have (or can operate at) a voltage of at least about 0V, 0.1V, 0.2V, 0.3V, 0.4V, 0.5V, 0.6V, 0.7V, 0.8V, 0.9V, 1.0V, 1.1V, 1.2V, 1.3V, 1.4V, 1.5V, 1.6V, 1.7V, 1.8V, 1.9V, 2.0V, 2.1V, 2.2V, 2.3V, 2.4V, 2.5V, 2.6V, 2.7V, 2.8V, 2.9V, or 3.0V. In some examples, the monomer can have an Open Circuit Voltage (OCV) of at least about 0.2V, 0.3V, 0.4V, 0.5V, 0.6V, 0.7V, 0.8V, 0.9V, 1.0V, 1.1V, 1.2V, 1.3V, 1.4V, 1.5V, 1.6V, 1.7V, 1.8V, 1.9V, 2.0V, 2.1V, 2.2V, 2.3V, 2.4V, 2.5V, 2.6V, 2.7V, 2.8V, 2.9V, or 3.0V. In one example, the monomer has an open circuit voltage greater than about 0.5V, 1V, 2V, or 3V. In some examples, the Charge Cutoff Voltage (CCV) of the monomer in the charged state is from greater than or equal to about 0.5V to 1.5V, 1V to 3V, 1.5V to 2.5V, 1.5V to 3V, or 2V to 3V. In some examples, the charge cut-off voltage (CCV) of the monomer is at least about 0.5V, 0.6V, 0.7V, 0.8V, 0.9V, 1.0V, 1.1V, 1.2V, 1.3V, 1.4V, 1.5V, 1.6V, 1.7V, 1.8V, 1.9V, 2.0V, 2.1V, 2.2V, 2.3V, 2.4V, 2.5V, 2.6V, 2.7V, 2.8V, 2.9V, or 3.0V. In some examples, the voltage (e.g., operating voltage) of the cells in the charged state is between about 0.5V and 1.5V, 1V and 2V, 1V and 2.5V, 1.5V and 2.0V, 1V and 3V, 1.5V and 2.5V, 1.5V and 3V, or 2V and 3V. The monomer can provide such voltage(s) (e.g., voltage, OCV, and/or CCV) when operated at up to and in excess of about 10 cycles, 20 cycles, 30 cycles, 40 cycles, 50 cycles, 100 cycles, 200 cycles, 300 cycles, 400 cycles, 500 cycles, 600 cycles, 700 cycles, 800 cycles, 900 cycles, 1,000 cycles, 2,000 cycles, 3,000 cycles, 4,000 cycles, 5,000 cycles, 10,000 cycles, 20,000 cycles, 50,000 cycles, 100,000 cycles, or 1,000,000 cycles or more (also referred to herein as "charge/discharge cycles").

In some examples, unlike the chemistry of the negative electrode, electrolyte, and/or positive electrode, the limiting factor for the number of cycles may depend on the housing and/or seal, for example. The limitation in circulation may not be determined by the electrochemical process but by degradation of inactive components of the monomer, such as the container or seal. The monomer can be operated without a significant reduction in capacity. In some cases, the operational service life of the cell may be limited by the life of the cell's container, seal, and/or cap. During operation of the cell at the operating temperature, the cell may have a negative electrode, an electrolyte, and a positive electrode in a liquid (or molten) state.

The electrochemical cells of the present disclosure may have a response time of any suitable value (e.g., suitable for responding to a disturbance in an electrical grid). In some cases, the response time is less than or equal to about 100 milliseconds (ms), 50ms, 10ms, 1ms, and the like. In some examples, the response time is at most about 100ms, 50ms, 10ms, 1ms, and the like.

The monomer may be hermetically or non-hermetically sealed. Further, in a group of cells (e.g., a battery), each cell may be hermetically or non-hermetically sealed. If the cells are not hermetically sealed, a cell stack or battery (e.g., several cells in series or parallel) may be hermetically sealed.

The seal may be made hermetic by one or more methods. For example, the seal may be subjected to relatively high compressive forces between the container lid and the container (e.g., greater than about 1,000psi or 10,000psi) in order to provide a seal in addition to electrical isolation. Alternatively, the seal may be bonded by a weld, braze joint, or other chemical bonding material joining the associated monolithic assembly to the insulating sealant material.

In one example, the unitary housing includes a conductive container, a container aperture, and a conductor in electrical communication with the current collector. The conductor may pass through the container aperture and may be electrically isolated from the conductive container. The housing may be capable of hermetically sealing a cell capable of storing at least about 10Wh of energy.

Fig. 2 schematically illustrates a battery including a conductive housing 201 and a conductor 202 in electrical communication with a current collector 203. The battery of fig. 2 may be a single cell of an energy storage device. The conductor may be electrically isolated from the housing and may protrude through the housing through an aperture in the housing such that when the first cell is stacked with the second cell, the conductor of the first cell is in electrical communication with the housing of the second cell.

In some examples, the cell includes a negative current collector, a negative electrode, an electrolyte, a positive electrode, and a positive current collector. The negative electrode may be part of a negative current collector. Alternatively, the negative electrode is spaced apart from, but otherwise in electronic communication with, a negative current collector. The positive electrode may be part of the positive current collector. Alternatively, the positive electrode may be spaced apart from, but otherwise in electronic communication with, the positive current collector.

The monomer may include an electronically conductive housing and a conductor in electronic communication with the current collector. The conductor protrudes through the housing through an aperture in the housing and may be electrically isolated from the housing.

The cell housing can include a conductive container and a conductor in electrical communication with the current collector. The conductor may protrude through the housing and/or the container through an aperture in the container and may be electrically isolated from the container. The conductor of the first housing may contact the receptacle of the second housing when the first housing and the second housing are stacked.

In some cases, the area of the aperture through which the conductor protrudes from the housing and/or container is small relative to the area of the housing and/or container. The ratio of the area of the aperture to the area of the container and/or housing may be less than or equal to about 0.5, 0.4, 0.3, 0.2, 0.15, 0.1, 0.05, 0.01, 0.005, or 0.001 (e.g., less than about 0.1).

The housing can enclose a monomer that can store, receive, and/or release any suitable amount of energy, as described in more detail elsewhere herein. For example, the housing can enclose a monomer capable of storing, receiving, and/or releasing less than about 100Wh, equal to about 100Wh, greater than about 100Wh, or at least about 10Wh or 25Wh energy.

Characteristics and Properties of the seal

The seal can be an important component of a high temperature system (e.g., a liquid metal battery) that contains reactive materials. Provided herein is a method for selecting materials suitable for forming a seal and a method for designing a suitable seal for a system (such as a liquid metal battery, for example) containing a reactive liquid metal or liquid metal vapor and/or a reactive molten salt(s) or reactive molten salt vapor(s) (e.g., based on the selection of these materials and consideration of thermal, mechanical, and electrical properties). The seal may also be used as part of an electrically isolated feedthrough in connection with a vessel containing a reactive liquid metal or reactive metal vapor for applications other than energy storage, such as fusion reactors containing molten or high pressure Li vapor or other applications involving liquid sodium, potassium, magnesium, calcium and/or lithium. The use of stable ceramics and conductive materials may also be suitable for applications with reactive gases such as those used in semiconductor material processing or device fabrication.

The seal may be electrically insulating and airtight (e.g., hermetic). The seal may be made of a material that is not eroded by the liquid and vapor phases (e.g., monomer components) of the system/vessel components, such as, for example, molten sodium (Na), molten potassium (K), molten magnesium (Mg), molten calcium (Ca), molten lithium (Li), Na vapor, K vapor, Mg vapor, Ca vapor, Li vapor, or any combination thereof. The method will include aluminum nitride (AlN) or silicon nitride (Si)₃N₄) Seals of ceramic and reactive alloy braze joints (e.g., Ti, Fe, Ni, B, Si, or Zr alloy based) are identified as thermodynamically stable with the most reactive metal vapors, thereby allowing for a design for seals that are not significantly attacked by the metal or metal vapors.

In some embodiments, the seal may physically separate the current lead (e.g., a negative current collector such as a metal rod extending into the cell cavity) from the oppositely polarized (e.g., positively polarized) cell body (e.g., the cell (also referred to herein as a "can") and the lid). The seal may act as an electrical insulator between the cell components and hermetically isolate the active cell components (e.g., liquid metal electrodes, liquid electrolyte, and vapors of the liquids). In some examples, the seal prevents external elements from entering the monomer (e.g., moisture, oxygen, nitrogen, and other contaminants that may adversely affect the performance of the monomer). Some examples of general seal specifications are listed in table 1. Such specifications (e.g., properties and/or metrics) may include, but are not limited to, hermeticity, electrical insulation, durability, coulombic efficiency (e.g., charge efficiency or round-trip efficiency), DC-DC efficiency, discharge time, and rate of capacity fade

TABLE 1 examples of general seal specifications

The seal can be hermetic, e.g., to the extent quantified by the helium (He) leak rate (e.g., the leak rate from a device filled with He under operating conditions (e.g., at operating temperature, operating pressure, etc.). In some examples, a helium (He) leak rate may be less than about 1 × 10^-6Atmospheric cubic centimeter per second (atmcc/s), 5X10^-7atm cc/s、1×10^-7atm cc/s、5×10^-8atm cc/s or 1X10^-8atm cc/s. In some examples, the He leakage rate is equivalent to the total leakage rate of He exiting the system (e.g., monomer, seal). In some examples, if one atmosphere of He pressure is applied across the sealed interface, the He leak rate is equivalent to the total leak rate of He, as determined by the actual He pressure/concentration difference across the sealed interface and the measured He leak rate.

The seal may provide any suitable low helium leakage rate. In some examples, the seal provides no greater than or equal to about 1x10 at a temperature (e.g., storage temperature of the monomer, operating temperature of the monomer, and/or temperature of the seal) that is greater than or equal to about-25 ℃,0 ℃, 25 ℃,50 ℃,200 ℃, 350 ℃, 450 ℃, 550 ℃, or 750 ℃^-10、1x10^-9、1x10^-8、1x10^-7、5x10^-7、1x10^-6、5x10^-6、1x10^-5Or 5x10^-5Atmospheric pressure-cubic centimeter per second (atm-cc/s) helium leak rate. When the electrochemical cell has been operated (e.g., inRated capacity), for example, for a period of at least about 1 hour, 12 hours, 1 day, 2 days, 3 days, 4 days, 5 days, 1 week, 2 weeks, 3 weeks, 1 month, 6 months, 1 year, 2 years, 5 years, 10 years, 20 years, or more. In some examples, the seal provides such a helium leak rate when the electrochemical cell has been operated for at least about 350 charge/discharge cycles (or cycles), 500 cycles, 1,000 cycles, 3,000 cycles, 10,000 cycles, 50,000 cycles, 75,000 cycles, or 150,000 cycles.

In one example, the seal is substantially non-reactive to air and prevents air from diffusing into the container when the reactive material is maintained at a temperature of at least about 200 ℃, 250 ℃, 300 ℃, 350 ℃, 400 ℃, 450 ℃,500 ℃ or more. The seal can prevent diffusion of air into the container for at least about 1 hour, 12 hours, 1 day, 2 days, 3 days, 4 days, 5 days, 1 week, 2 weeks, 3 weeks, 1 month, 6 months, 1 year, 2 years, 5 years, 10 years, 20 years, or more. The diffusion of air into the container may be up to about 1x10^-4、1x10^-5、1x10^-6、1x10^-7、1x10^-8、1x10^-9、1x10^-10Or lower atmospheric pressure-cubic centimeters per second.

The seal may electrically isolate the conductor from the conductive housing. The degree of electrical isolation can be quantified by measuring the impedance across the seal. In some examples, the impedance across the seal is greater than or equal to about 0.05 kilo-ohms (kOhm), 0.1kOhm, 0.5kOhm, 1kOhm, 1.5kOhm, 2kOhm, 3kOhm, 5kOhm, 10kOhm, 50kOhm, 100kOhm, 500kOhm, 1,000kOhm, 5,000kOhm, 10,000kOhm, 50,000kOhm, 100,000kOhm, or 1,000,000kOhm at any operating, quiescent, or storage temperature. In some examples, the impedance across the seal is less than about 0.1kOhm, 1kOhm, 5kOhm, 10kOhm, 50kOhm, 100kOhm, 500kOhm, 1,000kOhm, 5,000kOhm, 10,000kOhm, 50,000kOhm, 100,000kOhm, or 1,000,000kOhm at any operating, quiescent, or storage temperature. The seal may provide electrical isolation when the electrochemical cell has been in operation, for example, for a period of at least about 1 month, 6 months, 1 year, or more. In some examples, the seal provides electrical isolation when the electrochemical cell has been operated for at least about 350 charge/discharge cycles (cycles), 500 cycles, 1,000 cycles, 3,000 cycles, 10,000 cycles, 50,000 cycles, 75,000 cycles, 150,000 cycles. The seal may provide electrical isolation when the electrochemical cell has been in operation for a period of at least about 1 year, 5 years, 10 years, 20 years, 50 years, or 100 years. In some examples, the seal provides electrical isolation when the electrochemical cell has been operated for greater than or equal to about 350 charge/discharge cycles.

The seal may be durable. In some examples, the seal may maintain integrity for at least 1 month, 2 months, 6 months, 1 year, 2 years, 5 years, 10 years, 15 years, 20 years, or more. The seal may have such properties and/or metrics under operating conditions.

In some examples, a cell or device including a seal can have a coulombic efficiency of at least about 50%, 55%, 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95%, 96%, 97%, 98%, 99%, 99.5%, 99.8%, 99.9% or more (e.g., at a current density of about 20 mA/cm)²、200mA/cm²Or 2,000mA/cm²Measured as follows). In some examples, a cell or device including a seal can have a DC-DC efficiency (e.g., at a current density of about 200 mA/cm) of at least about 50%, 55%, 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95%, or more²Or 220mA/cm²Measured as follows). In some examples, a battery or device including a seal can have a discharge time of at least about 1 hour, 2 hours, 3 hours, 4 hours, 5 hours, 6 hours, 7 hours, 8 hours, 9 hours, 10 hours, or more (e.g., at a current density of about 200 mA/cm)²Or 220mA/cm²Measured below). In some examples, a battery or device including a seal can have a discharge time (e.g., at a current density of about 200 mA/cm) of between about 4 hours and 6 hours, 2 hours and 6 hours, 4 hours and 8 hours, or 1 hour and 10 hours²Or 220mA/cm²Measured as follows). In some examples, a battery or device including a seal can have less than aboutCapacity fade rates (e.g., discharge capacity fade rates) of 10%/cycle, 5%/cycle, 1%/cycle, 0.5%/cycle, 0.1%/cycle, 0.08%/cycle, 0.06%/cycle, 0.04%/cycle, 0.02%/cycle, 0.01%/cycle, 0.005%/cycle, 0.001%/cycle, 0.0005%/cycle, 0.0002%/cycle, 0.0001%/cycle, 0.00001%/cycle, or less. The rate of capacity fade can provide a measure of the change (decrease) in discharge capacity in "% per cycle" (e.g., in%/charge/discharge cycle).

In some examples, the seal allows the electrochemical cell to be implemented at one or more given operating conditions (e.g., operating temperature, temperature cycling, voltage, current, internal gas pressure, internal pressure, vibration, etc.). Some examples of operating conditions are described in table 2. Such operating conditions may include, but are not limited to, metrics such as operating temperature, idle temperature, temperature cycling, voltage, current, internal air pressure, external air pressure, internal pressure, vibration, and service life, to name a few.

Table 2: examples of operating conditions of the monomers

In some examples, the operating temperature (e.g., the temperature to which the seal is subjected during operation) is at least about 100 ℃,200 ℃, 300 ℃, 400 ℃,500 ℃, 600 ℃, 700 ℃, 800 ℃, 900 ℃ or more. In some examples, the temperature to which the seal is subjected during operation is between about 440 ℃ and 550 ℃, 475 ℃ and 550 ℃, 350 ℃ and 600 ℃, or 250 ℃ and 650 ℃. In one example, an operating temperature of about 400 ℃ to about 500 ℃, about 450 ℃ to about 550 ℃, about 450 ℃ to about 500 ℃, or about 500 ℃ to about 600 ℃, or an operating temperature of at least about 200 ℃ may be achieved (e.g., suitable for a monomer chemistry that can operate at as low as 200 ℃). In some examples, the temperature to which the seal is subjected may be about equal to the operating temperature of the electrochemical cell or a high temperature device (e.g., an energy storage device). In some examples, the temperature to which the seal is subjected can be different (e.g., by at least less than or equal to about 1 ℃,5 ℃, 10 ℃,20 ℃,50 ℃, 100 ℃, 150 ℃,200 ℃, etc.) from the operating temperature of the electrochemical cell or high temperature device. In one example, the electrochemical cell includes a reactive material maintained at a temperature of at least about 200 ℃ (e.g., the operating temperature of the cell), while the temperature of the seal is at least about 200 ℃ (e.g., the same as or different from the operating temperature of the cell). In some examples, the operating temperature of the seal may be lower or higher than the operating temperature of the electrochemical cell or the high temperature device.

Chemical stability of the material (e.g., the unitary cap assembly material, the one or more adhesive sealing materials, etc.) may be considered (e.g., to ensure durability of the seal during all possible temperatures that the system may reach). The seal may be exposed to one or more different atmospheres, including the monomer interior (internal atmosphere) and the open air (external atmosphere). For example, the seal may be exposed to typical air components containing moisture, as well as to potentially corrosive active materials in the monomer. In some embodiments, a hermetic seal is provided. A hermetically sealed battery or battery enclosure may prevent an undue amount of air, oxygen, nitrogen, and/or water from leaking or otherwise entering the battery. A hermetically sealed battery or battery housing can prevent an undue amount of one or more gases (e.g., air or any component(s) thereof, or other types of ambient atmosphere or any component(s) thereof) from leaking or otherwise entering the battery from around the battery. In some examples, a hermetically sealed cell or cell enclosure may prevent gas or metal/salt vapors (e.g., helium, argon, negative electrode vapors, electrolyte vapors) from leaking from the cell.

A hermetically sealed battery or battery enclosure can prevent an improper amount of air, oxygen, and/or water from entering the battery (e.g., an amount that is at least about 1 year, 2 years, 5 years, 1 year after the battery has been in serviceAt least about 100mA/cm in 0 or 20 years²Such that the battery maintains at least about 80% of its energy storage capacity and/or maintains at least about 90% round-trip coulombic efficiency per cycle when charged and discharged). In some cases, when the battery is contacted with air at a pressure of at least about (or less than about) 0 atmosphere (atm), 0.1atm, 0.2atm, 0.3atm, 0.4atm, 0.5atm, 0.6atm, 0.7atm, 0.8atm, 0.9atm, or 0.99atm higher or lower than the internal pressure of the battery and at a temperature of about 400 ℃ to about 700 ℃, the rate of transfer of oxygen, nitrogen, and/or water vapor into the battery is less than about 0.25 milliliters (mL) per hour, 0.02mL per hour, 0.002mL per hour, or 0.0002mL per hour. In some cases, when the battery is contacted with air at a pressure greater than or equal to about 0.5atm, 1atm, 1.5atm, 2atm, 2.5atm, 3atm, 3.5atm, or 4atm less than the internal pressure of the battery and at a temperature of about 400 ℃ to about 700 ℃, the rate at which the metal vapor, molten salt vapor, or inert gas is transferred out of the battery is less than 0.25mL per hour, 0.02mL per hour, 0.002mL per hour, or 0.0002mL per hour. In some examples, the moles of oxygen, nitrogen, or water vapor that leaks into the monomer over a given period of time (e.g., at least about a 1 month period, a 6 month period, a 1 year period, a 2 year period, a 5 year period, a 10 year period, or more) is less than about 10%, 5%, 3%, 1%, 0.5%, 0.1%, 0.05%, or 0.5% of the moles of active material (e.g., active metal material) in the monomer.

The seal may meet one or more specifications, including but not limited to: electrical insulation and containment, ability to continue to operate over a lifetime at operating temperatures, thermal cycling ability, sufficiently high electrical conductivity of the conductor (e.g., negative current lead), configuration that does not protrude excessively from the monomer body, internal surfaces chemically stable with liquids and vapors of active components, external surfaces stable in air, ability to avoid arcing at high potentials, and the like.

Material, chemical compatibility and coefficient of thermal expansion

The materials and features of the seals herein may be configured to achieve suitable material (e.g., chemical, mechanical, thermal) compatibility. Material compatibility may include, for example, a Coefficient of Thermal Expansion (CTE), a suitable young's modulus characteristic (e.g., a low young's modulus metallic material), and/or a suitable match of ductility characteristics (e.g., one or more components having high ductility). The seal may incorporate structural features that can compensate for CTE mismatch.

The materials may be selected to achieve a low CTE mismatch between the various (e.g., paired) seal materials and/or housing (e.g., unitary cover and/or body) materials. The materials may be selected to achieve low stress (e.g., stress due to CTE mismatch) at the joint(s) between the various (e.g., paired) seal materials and/or housing materials. The joints between the various seal materials and/or housing materials may be of a given type (e.g., ceramic to metal or metal to metal). In one example, the ceramic material has a CTE that is suitably (e.g., substantially) matched to the CTE of the unitary cover or body, thereby reducing or minimizing stress(s) (e.g., stress(s) at one or more ceramic-to-metal joints between the ceramic material and the unitary cover or body). In some examples, the CTE of the ceramic material is suitably (e.g., substantially) different than the CTE of the unitary cover or body. In this case, a metal collar or sleeve may be used that has a better CTE match or has one or more other properties that reduce stress in the ceramic to metal joint. The metal collar or sleeve may move CTE stresses from a ceramic joint (e.g., from a ceramic to metal joint between the ceramic and metal collar or sleeve) to a unitary cap or body joint (e.g., to a metal to metal joint between the metal collar or sleeve and the unitary cap or body). The CTE of the ceramic material may suitably (e.g., substantially) match the CTE of the metal collar or sleeve. The CTE of the ceramic material may suitably (e.g. substantially) be different from the CTE of the metal collar or sleeve. For example, ceramic-to-metal seal joint stress(s) may be reduced by using a ductile metal collar or sleeve (e.g., comprising at least about 95% or 99% Ni) and/or by using a ductile brazing material (e.g., comprising at least about 95% or 99% Ag, Cu, or Ni). Ductile brazing materials may be used to reduce stress(s) at the ceramic-to-metal joint between the ceramic and the unitary cap or body or to reduce stress(s) at the ceramic-to-metal joint between the ceramic and the metal collar or sleeve.

The seal may be made of any suitable material (e.g., such that the seal forms a hermetic seal and electrical isolation). In some examples, the seal includes a ceramic material and a braze material. The ceramic material may have a CTE that matches the housing material such that the electrochemical cell maintains suitable gas-tight and/or electrical insulating properties during operation and/or start-up of the battery. The ceramic material may have a CTE that matches the CTE of the braze material and/or the monolithic top (e.g., cap or cap, or any component of the monolithic cap assembly) or body. In some examples, the CTEs of the ceramic material, the braze material, and the monolithic top or body may not be the same match, but may be close enough to minimize stress during the brazing operation and subsequent thermal cycles in the operation. In some examples, the CTE of the ceramic material may not be close enough to the CTE of the monolithic top or body (e.g., resulting in unstable and/or unreliable ceramic-to-metal joints in some cases, which may lose their non-leaking properties). The seal may comprise a collar (e.g., a thin metal collar) or a sleeve (e.g., to overcome CTE mismatch between the ceramic material and the unitary cap or unitary body). The collar or sleeve may be a metal collar or sleeve. The collar or sleeve may be brazed onto the ceramic (e.g., via a brazing material) and joined to the cell lid and/or the current lead that protrudes through the cell lid and into the cell cavity. Suitable collar or sleeve materials and/or designs may be selected to reduce stresses generated at the ceramic to metal joint (e.g., by reducing CTE mismatch), to increase stresses generated at the collar or sleeve to monolithic cap or body joint (e.g., by increasing CTE mismatch), or combinations thereof. The seal may include features to mitigate CTE mismatch between the ceramic and the unitary cover and/or the current lead stem. Any aspect of the disclosure (e.g., CTE, joint stress, configuration and/or formation, etc.) described with respect to the monolithic top or body may be equally applicable to the monolithic top and body, at least in some configurations. Any aspect of the disclosure described with respect to the monomer top may be equally applicable to the monomer body, at least in some configurations, and vice versa.

The CTE of the metal collar or sleeve can be at least about 5, 6, 10, 11, 12, 13, 16, 14, 16, 17, 18, 19, or 20 μm/m/c. The CTE of the metal collar or sleeve can be less than or equal to about 20, 19, 14, 13, 12, 9, 8, 7, 6, or 5 μm/m/c. In some examples, the metal collar or sleeve comprises Zr and has a CTE less than or equal to about 7 μm/m/° c. In some examples, the metal collar or sleeve comprises Ni (e.g., at least about 95% or 99% Ni, or at least about 40% Ni and at least about 40% Fe by weight) and has a CTE greater than or equal to about 6, 7, 8, 9, 10, 12, 13, 14, 15, 16, 17, 18, 19, or 20 μm/m/° c. The metal collar or sleeve may comprise greater than or equal to about 5%, 10%, 15%, 20%, 25%, 30%, 31%, 32%, 33%, 34%, 35%, 36%, 37%, 38%, 39%, 40%, 41%, 42%, 43%, 44%, 45%, 46%, 47%, 48%, 49%, 50%, 51%, 52%, 53%, 54%, 55%, 56%, 57%, 58%, 59%, 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95%, or 99% Ni (e.g., by weight). The metal collar or sleeve may comprise a Ni composition in combination with greater than or equal to about 5%, 10%, 15%, 20%, 25%, 30%, 31%, 32%, 33%, 34%, 35%, 36%, 37%, 38%, 39%, 40%, 41%, 42%, 43%, 44%, 45%, 46%, 47%, 48%, 49%, 50%, 51%, 52%, 53%, 54%, 55%, 56%, 57%, 58%, 59%, 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95%, or 99% Fe (by weight). Such Ni or Ni-Fe compositions (e.g., alloys) can include one or more other elements (e.g., C, Co, Mn, P, S, Si, Cr, and/or Al) in individual or total concentrations less than or equal to about 1%, 0.9%, 0.8%, 0.7%, 0.6%, 0.5%, 0.4%, 0.3%, 0.15%, 0.1%, 0.09%, 0.08%, 0.07%, 0.06%, 0.05%, 0.04%, 0.03%, 0.025%, 0.01%, or 0.005%. In some examples, the metal collar or sleeve comprises greater than or equal to about 50.5% Ni, greater than or equal to about 48% Fe, and less than or equal to about 0.60% Mn, 0.30% Si, 0.005% C, 0.25% Cr, 0.10% Co, 0.025% P, and/or 0.025% S (e.g., alloy 52). In some examples, the metal collar or sleeve includes greater than or equal to about 41% Ni, greater than or equal to about 58% Fe, and less than or equal to about 0.05% C, 0.80% Mn, 0.40% P, 0.025% S, 0.30% Si, 0.250% Cr, and/or 0.10% Al (e.g., alloy 42). In some examples, the metal collar or sleeve includes an Fe alloy having between about 17.5% and 19.5% Cr, between about 0.10% and 0.50% Ti, between about 0.5% and 0.90% niobium, less than or equal to about 1% Ni, 1% Si, 1% Mn, 0.04% phosphorous, 0.03% nitrogen, 0.03% sulfur, and/or 0.03% carbon, and the balance Fe (e.g., 18CrCb ferritic stainless steel). Such Fe alloys (e.g., 18CrCb ferritic stainless steels) may have a CTE of about 8ppm/K, 9ppm/K, 10ppm/K, 11ppm/K, or 12 ppm/K. In some examples, the metal collar or sleeve comprises an Fe alloy having between about 17.5% and 18.5% Cr, between about 0.10% and 0.60% Ti, between about 0.3% and 0.90% niobium, less than about 1% Si, 1% Mn, 0.04% phosphorus, 0.015% sulfur, and/or 0.03% carbon, and the balance Fe (e.g., grade 441 stainless steel). Such Fe alloys (e.g., grade 441 stainless steel) may have a CTE of about 9ppm/K, 10ppm/K, 11ppm/K, 12ppm/K, 13ppm/K, or 14 ppm/K. In some examples, the metal collar or sleeve comprises a Ni alloy having at least about 72% Ni, between about 14% and 17% Cr, between about 6% and 10% Fe, and less than about 0.15% C, 1% Mn, 0.015% S, 0.50% Si, and/or 0.5% Cu (e.g., Inconel 600). Such a Ni alloy (e.g., Inconel 600) can have a CTE of about 12ppm/K, 13ppm/K, 14ppm/K, 15ppm/K, 16ppm/K, or 17 ppm/K. In some examples, the metal collar or sleeve comprises a Ni alloy having less than about 0.05% C, 0.25% Mn, and/or 0.002% S, less than or equal to about 0.20% Si, 15.5% Cr, 8% Fe, and/or 0.1% Cu, and the balance Ni and Co (e.g., ATI alloy 600). Such a Ni alloy (e.g., ATI alloy 600) may have a CTE of about 12ppm/K, 13ppm/K, 14ppm/K, 15ppm/K, 16ppm/K, or 17 ppm/K. In some examples, the metal collar or sleeve comprises greater than or equal to about 67% Ni, less than about 2% Co, 0.02% C, 0.015% B, 0.35% Cu, 1.0% W, 0.020% P, and/or 0.015% S, between about 14.5% and 17% Cr, between about 14% and 16.5% Mo, between about 0.2% and 0.75% Si, between about 0.30% and 1.0% Mn, between about 0.10% and 0.50% Al, between about 0.01% and 0.10% La, and less than or equal to about 3% Fe (e.g., hastelloy S). Such alloys (e.g., Hastelloy S) can have a CTE of about 12ppm/K, 13ppm/K, 14ppm/K, 15ppm/K, 16ppm/K, or 17 ppm/K. The metal collar or sleeve may have the aforementioned CTE values for, for example, a temperature range of about 25 ℃ to 400 ℃,20 ℃ to 500 ℃, 25 ℃ to 600 ℃, 25 ℃ to 900 ℃, or 25 ℃ to 1000 ℃.

The seal may include one or more braze materials (e.g., the same or different braze material at different joints when a metal collar or sleeve is used, or one braze material when a ceramic material is directly joined to the unitary cap or body). The CTE of the braze material can be at least about 3 micrometers per meter per degree celsius (μm/m/c), 4 μm/m/c, 5 μm/m/c, 6 μm/m/c, 7 μm/m/c, 8 μm/m/c, 9 μm/m/c, 10 μm/m/c, 11 μm/m/c, 12 μm/m/c, 13 μm/m/c, 14 μm/m/c, 15 μm/m/c, 16 μm/m/c, 17 μm/m/c, 18 μm/m/c, 19 μm/m/c, or 20 μm/m/c. The CTE of the braze material can be less than or equal to about 3 micrometers per meter per degree Celsius (μm/m/deg.C), 4 μm/m/deg.C, 5 μm/m/deg.C, 6 μm/m/deg.C, 7 μm/m/deg.C, 8 μm/m/deg.C, 9 μm/m/deg.C, 10 μm/m/deg.C, 11 μm/m/deg.C, 12 μm/m/deg.C, 13 μm/m/deg.C, 14 μm/m/deg.C, 15 μm/m/deg.C, 16 μm/m/deg.C, 17 μm/m/deg.C, 18 μm/m/deg.C, 19 μm/m/deg.C, or 20 μm/m/deg.C. The braze material may have a CTE value for a temperature range of, for example, about 25 ℃ to 400 ℃,20 ℃ to 500 ℃, 25 ℃ to 600 ℃, 25 ℃ to 900 ℃, or between 25 ℃ to 1000 ℃.

The stress(s) of the ceramic-to-metal joint may be reduced by using a brazing material of suitable (e.g., sufficient) ductility. The ductile brazing material may include silver (Ag), copper (Cu), and/or nickel (Ni). The braze material may comprise, for example, at least about 95% or 99% Ag (e.g., by weight), at least about 95% or 99% Cu (e.g., by weight), or at least about 95% or 99% Ni (e.g., by weight). The braze material may include any suitable ductile braze material described herein. The ductile brazing material may have a yield strength of less than or equal to about 10, 20, 30, 40, 50, 60, 70, 80, 90, 100, 150, 200, 250, 300, 350, 400, 450, 500, 600, 700, 800, 900, or 1000 Mpa. The braze material can have such a yield strength at a temperature of, for example, greater than or equal to about 25 ℃, 400 ℃,500 ℃, 600 ℃, 700 ℃, 800 ℃, 900 ℃, 1000 ℃, or 1100 ℃. In some examples, the brazing material may be coated (e.g., Ni coated).

The seal may include one or more metallized materials (e.g., metallized powder). The CTE of the metallization material (e.g., after formation of the metallization layer) can be at least about 3 μm/m/c, 4 μm/m/c, 5 μm/m/c, 6 μm/m/c, 7 μm/m/c, 8 μm/m/c, 9 μm/m/c, 10 μm/m/c, 11 μm/m/c, 12 μm/m/c, 13 μm/m/c, 14 μm/m/c, 15 μm/m/c, 16 μm/m/c, 17 μm/m/c, 18 μm/m/c, 19 μm/m/c, or 20 μm/m/c. The CTE of the metallization material (e.g., after formation of the metallization layer) can be less than or equal to about 3 microns per meter per degree celsius (μm/m/c), 4 μm/m/c, 5 μm/m/c, 6 μm/m/c, 7 μm/m/c, 8 μm/m/c, 9 μm/m/c, 10 μm/m/c, 11 μm/m/c, 12 μm/m/c, 13 μm/m/c, 14 μm/m/c, 15 μm/m/c, 16 μm/m/c, 17 μm/m/c, 18 μm/m/c, 19 μm/m/c, or 20 μm/m c. The metallization material may have CTE values for, for example, temperature ranges between about 25 ℃ and 400 ℃,20 ℃ and 500 ℃, 25 ℃ and 600 ℃, 25 ℃ and 900 ℃, or 25 ℃ and 1000 ℃. The young's modulus of the metallization material may be less than about 50 gigapascals (GPa), 75GPa, 100GPa, 150GPa, or 500 GPa. The metallization material may have a young's modulus value for temperatures of, for example, 25 °, 300 °, 400 °,500 °, 600 °, 900 ℃, or 1000 ℃. The metallization material may be chemically stable in air and/or at temperatures greater than or equal to about 200 ℃, 300 ℃, 400 ℃,500 ℃, 600 ℃, 900 ℃, or 1000 ℃ when exposed to reactive materials in the device.

The seal may include a ceramic material and a braze material. In some examples, the ceramic material is stable (e.g., thermodynamically stable) when in contact with (e.g., not chemically reacting with) one or more reactive materials (e.g., a reactive liquid metal or a reactive liquid metal vapor, such as, for example, molten lithium, lithium vapor, or calcium metal). In some examples, the ceramic material (e.g., AlN, Nd) when in contact with air (or other type of external atmosphere)₂O₃) Is stable. In some examples, the ceramic material is stable with the molten salt, is substantially not attacked by the molten salt (e.g., the material may have a slight surface reaction, but does not progress to degradation or attack of a majority of the material), and is substantially not dissolved into the molten salt. Examples of ceramic materials include, but are not limited to, aluminum nitride (AlN), beryllium nitride (Be)₃N₂) Boron Nitride (BN), calcium nitride (Ca)₃N₂) Silicon nitride (Si)₃N₄) Alumina (Al)₂O₃) Beryllium oxide (BeO), calcium oxide (CaO), cerium oxide (CeO)₂Or Ce₂O₃) Erbium oxide (Er)₂O₃) Lanthanum oxide (La)₂O₃) Magnesium oxide (MgO), neodymium oxide (Nd)₂O₃) Samarium oxide (Sm)₂O₃) Scandium oxide (Sc)₂O₃) Ytterbium oxide (Yb)₂O₃) Yttrium oxide (Y)₂O₃) Zirconium oxide (ZrO)₂) Yttria Partially Stabilized Zirconia (YPSZ), boron carbide (B)₄C) Silicon carbide (SiC), titanium carbide (TiC), zirconium carbide (ZrC), titanium diboride (TiB)₂) Chalcogenide, quartz, glass, or any combination thereof. The ceramic material may be electrically insulating (e.g., the ceramic material may have a thickness of greater than about 10%²Ohm-cm、10⁴Ohm-cm、10⁶Ohm-cm、10⁸Ohm-cm、10¹⁰Ohm-cm、10¹²Ohm-cm、10¹⁴Ohm-cm or 10¹⁶Resistivity of Ohm-cm). The CTE of the ceramic material may be (e.g., substantially) similar (e.g., less than or equal to about 0.1%, 0.5%, 1%, 2%, 3%, 4%, 5%, 6%, 7%, 8%, 9%, 10%, 15%, 20%, 25%, 30%, 35%, 40%, 45%, or 50% different) to the CTE of a stainless steel (e.g., grade 430 stainless steel, 441 stainless steel, or 18CrCb ferritic stainless steel) or a nickel alloy (e.g., an alloy comprising greater than or equal to about 50% Ni and greater than or equal to about 48% Fe, such as, for example, alloy 52).

In some examples, the braze material includes one or more braze constituents such that at least one braze constituent has a lower solubility in the reactive material, the reactive material has a lower solubility in the at least one braze constituent, the braze constituent does not react with (e.g., does not form an intermetallic alloy with) the reactive material at an operating temperature of the device, and/or the braze constituent melts above the operating temperature of the device. The reactive material may be, for example, a reactive metal. In some examples, the braze material includes at least one braze component having low solubility in the reactive metal. In some examples, the reactive metal has low solubility in the brazing composition. In some examples, the braze composition does not form an intermetallic alloy with the reactive metal at the operating temperature of the device. In some examples, the brazing composition and/or the brazing material melts above the operating temperature of the device. In some examples, the brazing component(s) may include Ti, Ni, Y, Re, Cr, Zr, and/or Fe, and the reactive metal may include lithium (Li) and/or calcium (Ca).

Examples of braze component materials include, but are not limited to, aluminum (Al), beryllium (Be), copper (Cu), chromium (Cr), iron (Fe), manganese (Mn), molybdenum (Mo), nickel (Ni), niobium (Nb), rubidium (Rb), scandium (Sc), silver (Ag), tantalum (Ta), rhenium (Te), titanium (Ti), vanadium (V), yttrium (Y), zirconium (Zr), phosphorus (P), boron (B), carbon (C), silicon (Si), or any combination thereof. In some cases, the ceramic material includes aluminum nitride (AlN) and the braze material includes titanium (Ti). In some examples, the braze material includes a mixture of two or more materials (e.g., 3 materials). The materials may be provided in any ratio. For example, the braze joint may include a ratio of about 30: 30: 40 or 40: 40: 20 (e.g., in weight-%, atomic-%, mol-%, or volume-%). In some examples, the braze material includes a mixture of titanium, nickel, copper, and/or zirconium. In some cases, the braze comprises at least about 20, 30, or 40 weight-% titanium, at least about 20, 30, or 40 weight-% nickel, and at least about 20, 30, 40, 50, or 60 weight-% zirconium. In some cases, the braze comprises less than about 20, 30, or 40-wt% titanium, less than about 20, 30, or 40 wt-% nickel, and less than about 20, 30, 40, 50, or 60 wt-% zirconium. In some cases, the braze comprises about 18% Ti, about 60% Zr, about 22% Ni (e.g., on a weight-%, atomic-%, mol-%, or volume-%). In some cases, the braze comprises at least about 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, or more weight-%, atomic-%, mol-%, or volume-% titanium, nickel, or zirconium (or any other braze material herein). In some examples, the braze contains about 19-21 weight percent (wt%) Zr, 19-21 wt% Ni, 19-21 wt% Cu, and the remainder contains primarily or entirely Ti (i.e., "tipize 200"). In some examples, the braze contains about 61-63 wt% Zr, 19-21 wt% Ni, and the remainder contains mainly or entirely Ti (i.e., "TiZrNi" braze). In some examples, the braze contains about 29-31 wt% Ni, with the remainder comprising primarily or entirely Ti (i.e., "TiNi-70" braze). In some examples, the braze contains at least about 10 wt% or 15 wt% Ti (i.e., "Ti braze alloy"). In some cases, the braze comprises less than or equal to about 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, or more weight-%, atomic-%, mol-%, or volume-% of titanium, nickel, or zirconium (or any other braze material herein). In some examples, the braze contains greater than about 70 wt%, greater than about 74 wt%, greater than about 78 wt%, greater than about 82 wt%, greater than about 86 wt%, greater than about 90 wt%, greater than about 94 wt%, or more nickel. In some examples, the braze comprises between about 70 wt% and 80 wt%, between about 70 wt% and 90 wt%, between about 70 wt% and 95 wt%, between about 80 wt% and 90 wt%, or between about 80 wt% and 95 wt% nickel. In some examples, the braze contains between about 82 wt% and 94 wt% nickel. In some cases, the braze contains greater than or equal to about 70 wt% Ni (herein, "BNi braze"). In some cases, the braze contains greater than or equal to about 82% Ni, and less than or equal to about 7% Cr, 3% Fe, 4.5% Si, 3.2% B, and/or 0.06% C (e.g., BNi-2 braze). In some cases, the braze contains greater than or equal to about 82% Ni, and less than or equal to about 15% Cr, 4.0% B, and/or 0.06% C (e.g., BNi-9 braze). In some cases, the braze contains greater than or equal to about 82% Ni, and less than or equal to about 15% Cr, 7.3% Si, 0.06% C, and/or 1.4% B (e.g., BNi-5B braze). In some cases, the braze comprises yttrium, chromium, or rhenium, and nickel. In some examples, the braze includes silver (Ag) and aluminum (Al), and may also include titanium. The braze may include a ratio of silver to aluminum (Ag: Al) of about 5:1, 6:1, 7:1, 8:1, 9:1, 10:1, 11:1, 12:1, 13:1, 14:1, 15:1, 16:1, 17:1, 18:1, 19:1, 20:1, 25:1, or greater. In some examples, the braze contains a ratio of about 19:1Ag to Al by weight or volume (e.g., about 95 wt% Ag to about 5 wt% Al), and may also contain other additives, such as Ti.

To facilitate bonding of the ceramic material to the metal collar or sleeve using certain braze materials (e.g., non-active braze materials), the metal-containing layer (also referred to herein as "gold")Metallization layers "and" pre-metallization layers ") may be first applied to the ceramic material via a pre-metallization step (e.g., the metallization layers may be applied to the ceramic material by a coating process). For example, it may be applied by sputtering or by vacuum or controlled atmosphere (e.g., Ar or N)₂And H₂Gas) high temperature heat treatment (e.g., sintering a metallized layer onto a ceramic material) applies a metallized layer having a controlled layer thickness onto the ceramic material without bonding a metal collar or sleeve to the brazing material. The pre-metallization step may enable, for example, a subsequent brazing step to bond the pre-metallized ceramic surface to the metal collar or sleeve by using a brazing material that may not bond directly to the ceramic material (e.g., the brazing material may not bond to the ceramic material without the metallization layer).

The metallization layer may comprise a metallization material (also referred to herein as a "pre-metallization material"). As described in more detail elsewhere herein, the metallization material may comprise one or more metallic and/or non-metallic materials (e.g., one or more metals, ceramics, silica glass, etc.). Application of the metallization material may result in the formation of one or more pre-metallization layers. The sub-layer(s) may be formed in one step (e.g., a processing step using a single metallization material may result in the formation of two sub-layers) or may result from multiple processing steps (e.g., multiple processing steps using different metallization materials). The metallization material may comprise a brazing material. For example, at least a portion (e.g., some portion) of the braze material (e.g., yttrium, titanium, or aluminum) may be applied as a metallization material via a pre-metallization step. In some cases, the pre-metalized material may be referred to as a pre-metalized braze material. The metallization material may be different from the brazing material. In some cases, the material may be referred to as a metallization material rather than a brazing material. For example, when a metal coating is applied as a powder and the powder is bonded to a ceramic, the powder may be referred to as a metalized powder rather than a brazed powder. Such terms may distinguish between braze materials (e.g., powders) that may melt onto the ceramic and/or metal during heat treatment, and metallization materials that may effectively sinter onto the ceramic during heat treatment and may not melt (e.g., may not completely melt) during heat treatment.

In some embodiments, the ceramic to metal braze joint may be formed by a metallization process followed by a brazing process. In some embodiments, a metallization step may not be included, and the ceramic-to-metal braze joint may be formed directly by an active brazing step (e.g., using a Ti-containing braze).

The ceramic material may comprise AlN. The ceramic material may comprise a primary ceramic material (e.g., AlN) and one or more secondary ceramic materials (e.g., Y)₂O₃SiC, or combinations thereof). The ceramic material may be substantially or entirely formed of a primary ceramic material. The ceramic material may comprise various levels of secondary ceramic material(s). For example, the ceramic material may comprise a first secondary ceramic material and a second secondary ceramic material. The ceramic material can include a first secondary ceramic material (e.g., Y) at a concentration of greater than or equal to about 3 wt%₂O₃). Alternatively, the ceramic material may comprise a first secondary ceramic material (e.g., Y) at a concentration of less than about 3 wt%₂O₃). The ceramic material can include a combination of a first secondary ceramic material and at least a second secondary ceramic material (e.g., SiC) at a concentration of greater than or equal to about 25 wt% (or 25 volume-%) (also referred to herein as "v%", "vol%", and "volume percent"). In some examples, the ceramic material may include AlN as a primary ceramic material, and about 1 wt% to 5 wt% Y₂O₃As the second ceramic material.

The braze joint may be an inert braze joint or an active braze joint. The inert braze joint may melt and wet the ceramic material or wet the ceramic material with a metallization layer deposited thereon. Copper and silver are examples of inert braze joints. The active braze joint may react with the ceramic (e.g., chemically reducing the metal component of the ceramic (e.g., reducing Al from AlN)). In some examples, the active braze may contain a reactive metal species (e.g., AlN + Ti → Al + C) with a reactive metal species such as titanium (Ti) or zirconium (Zr) with the ceramic materialTiN or AlN + Zr → Al + ZrN or 2Nd₂O₃+3Ti→4Nd+3TiO₂) The metal alloy of (1). The active braze joint may also contain one or more inert components (e.g., Ni). The inert component(s) may, for example, lower the melting point of the braze joint and/or improve the chemical stability of the braze joint. In some cases, the active metal braze joint beads up on the ceramic and/or does not wet the ceramic.

The seal may be welded or brazed to the conductive housing, the unitary (housing) cover, and/or the conductor. In some examples, the conductive housing and/or conductor comprises 400 series stainless steel, 300 series stainless steel, nickel, steel, or any combination thereof. In some examples, the conductive housing and/or conductor comprises a low carbon stainless steel, such as 304L stainless steel (304L SS), for example. Low carbon stainless steel (e.g., 304L SS) may also be used in the metal collar and/or sleeve of the seal. In some examples, the sleeve comprises alloy 42, and the collar and conductor comprise low carbon stainless steel (e.g., 304L SS) and/or steel (e.g., low carbon steel). In some examples, the conductor includes a Ni coating (e.g., nickel plated low carbon steel). In some examples, the low carbon stainless steel may reduce unwanted chemical reactions with reactive materials within the monomer.

In some examples, the sleeve or collar material may include, for example, 304 stainless steel, 304L stainless steel, 430 stainless steel (430SS), 410 stainless steel, alloy 42, alloy 52, and nickel-cobalt iron alloy. In some examples, the sleeve or collar assembly may include a coating, such as a Ni coating (e.g., Ni-coated alloy 42). The brazing material may include, for example, nickel-100, molybdenum (Mo), and tungsten (W). The ceramic material may comprise, for example, aluminum nitride (AlN), aluminum oxide (Al)₂O₃) Boron Nitride (BN) oriented in a direction parallel to the crystal grains, Boron Nitride (BN) oriented in a direction perpendicular to the crystal grains, yttrium oxide (Y)₂O₃) And Yttria Partially Stabilized Zirconia (YPSZ).

In some examples, the conductive component of the seal comprises a metal having a low CTE (e.g., less than about 1 ppm/c, 2 ppm/c, 3 ppm/c, 4 ppm/c, 5 ppm/c, 6 ppm/c, 7 ppm/c, 8 ppm/c, 9 ppm/c, 10 ppm/c, 11 ppm/c, 12 ppm/c, or 15 ppm/c), a low young's modulus (e.g., less than about 0.1Gpa, 0.5Gpa, 1Gpa, 10Gpa, 50Gpa, 100Gpa, 150Gpa, 200Gpa, or 500Gpa), a high ductility (e.g., an ultimate strength greater than about 100%, 200%, 300%, 400%, or 500% of a yield strength), or any combination thereof. In some examples, the ultimate strength may be greater than about 50%, 100%, or 200% of the material yield strength to provide it with sufficient ductility. In some examples, the conductive component does not comprise a conductive ceramic. Low CTE, low young's modulus, and/or high ductility component properties may result in low stress concentrations in the ceramic. Low CTE, low Young's modulus, and/or high ductility component properties may reduce the likelihood of failure (e.g., due to reduced stress concentration and/or less stress generated) the metals that meet these specifications (in addition to corrosion resistance to internal and external monolithic environments) may include, for example, zirconium (Zr), high zirconium content alloys, tungsten (W), titanium (Ti), nickel (Ni), and/or molybdenum (Mo).

In some embodiments, the seal comprises a ceramic, one or more braze materials, and one or more metal collars. For example, two metal collars may be bonded to the ceramic, one on each side of the ceramic. Each such metal collar may also be joined to additional metal collar(s). Thus, a composite metal collar comprising two or more metal collars may be created. In some examples, the composite metal collar comprises at least two metal collars, wherein at least one metal collar comprises a material suitable for bonding (e.g., using one type of braze) to the ceramic and at least one metal collar comprises a material suitable for bonding (e.g., using another type of braze) to another component of the seal or cell. The two metal collars may also be joined (e.g., using yet another type of braze). In some cases, at least a portion (e.g., all) of the braze used to join the metal collars of the seal to each other and/or to other portions of the cell may be of the same type. In some examples, at least a portion or all of the braze may be of different types. Furthermore, the one or more metal collars may be welded instead of brazed, or both. The seal may comprise one or more composite metal collars. In some examples, the seal comprises a single metal collar of at least about 1,2, 3, 4, 5, 6, 7, 8, 9, 10, 12, 14, 16, 18, 20 or more. In one example, the seal comprises 3 or 4 individual metal collars forming two composite metal collars. In some examples, at least a portion of the single metal collar may comprise the same material. For example, a metal collar comprising the same material may be used to join the metal collar to a similar material (e.g., a similar monolithic housing or conductor material).

In some examples, the seal includes a ceramic, a braze material, a first (e.g., thin) metal collar, and/or a second metal collar. The first metal collar may be brazed to the ceramic and the second metal collar may be brazed to the first metal collar. In some examples, the first metal collar is a low CTE material such as alloy 42, zirconium (Zr), or tungsten (W) and the second metal collar is a ferrous alloy such as steel, stainless steel, 300 series stainless steel (e.g., 304L stainless steel), or 400 series stainless steel (e.g., 430 stainless steel). In some examples, the first metal collar is less than about 2 microns (μm), 5 μm, 10 μm, 20 μm, 50 μm, 100 μm, 150 μm, 250 μm, 500 μm, 1,000 μm, 1,500 μm, or 2,000 μm thick.

In some examples, the seal includes a ceramic, a braze, a first metal collar, a second metal collar, and a third metal collar. A first metal collar may be joined to a portion of the ceramic and a second metal collar may be joined to the first metal collar. The third metal collar may be joined to a different portion of the ceramic such that the first metal collar is separated from the third metal collar by an electrically insulating ceramic material. The joints between the first metal collar and the ceramic and between the third metal collar and the ceramic may both be hermetic. In some examples, the seal further includes a fourth metal collar joined to the third metal collar (e.g., the first metal collar is joined to a portion of the ceramic, the second metal collar is joined to the first metal collar, the third metal collar is joined to another portion of the ceramic and the fourth metal collar is joined to the third metal collar). The braze material used to join the first metal collar to the second metal collar may include or be similar to any braze composition described herein. The first metal collar or the second metal collar may be joined (e.g., joined using a brazing composition similar to any of the brazing compositions described herein, or welded) to the cell cap. The third metal collar may be joined to the fourth metal collar or directly to the negative current lead (e.g., brazed using any of the brazing compositions of the present disclosure).

Fig. 3 is a cross-section of a radially symmetric example of a seal 300 including a ceramic assembly 305. The ceramic component may comprise, for example, aluminum nitride (AlN). In some examples, the ceramic component may comprise yttria (Y)₂O₃). In one example, the ceramic component comprises about 3 weight percent or more yttria. In some examples, the ceramic component comprises about 1 percent to about 4 percent yttria. The ceramic component 305 is joined with a first metal sleeve (e.g., nickel-plated alloy 42)310 via a first metal-to-ceramic joint (e.g., braze) 355. The seal also includes a second metal sleeve (e.g., Ni-plated alloy 42)340 bonded to the ceramic component 305 via a second metal-to-ceramic joint (e.g., first braze alloy) 315. The first metal-to-ceramic joint 355 and the second metal-to-ceramic joint 315 may include, for example, a first braze alloy of silver and aluminum (Ag-Al). The first metal-to-ceramic joint 355 and the second metal-to-ceramic joint 315 may include a first braze alloy and an internal braze alloy. The first braze alloy may be exposed to an environment external to the vessel (e.g., ambient air), and the internal braze alloy may be exposed to an internal environment of the vessel (e.g., a high temperature reactive material). The first braze alloy may include a ductile material. The first braze may be an alloy of at least two different metals. The first braze alloy may have a silver to aluminum ratio of less than 19 to 1; for example,the first braze alloy may contain about 95% or less silver. The first braze alloy may also include a wetting agent. For example, the wetting agent may comprise titanium or titanium hydride. In some examples, the wetting agent may be provided as a metallization layer of the first braze alloy. For example, the

metal sleeves

310 and 340 may be brazed to the outer surface of the ceramic component.

The first metal-to-ceramic joint 355 and/or the second metal-to-ceramic joint 315 may also include an internal braze alloy. The internal braze alloy may be located at or near an inner surface of the first metal-to-ceramic joint 355 and/or the second metal-to-ceramic joint 315. The internal braze alloy may be more chemically stable than the first braze alloy. The internal braze may be an alloy of at least two different metals. The internal braze alloy may include a brittle material. The internal brazing alloy may be a reactive metal braze. The internal braze alloy may be stable when exposed to reactive metallic materials inside the sealed container (e.g., high temperature battery cell). The internal braze alloy may form a protective barrier between the reactive material and the first braze alloy. The first braze alloy may be exposed to the atmosphere outside the sealed vessel and may provide a barrier between the ambient atmosphere and the interior braze alloy. The internal braze alloy may comprise a Ni-based braze alloy (e.g., BNi-2, BNi-7, BNi-9) or a Ti braze alloy (e.g., TiBraze200, TiZrNi, TiNi-70). The bottom metal-to-ceramic joint 315 may comprise a first braze alloy of silver and aluminum, and the top metal-to-ceramic joint 355 may comprise both the first braze alloy of silver and aluminum (e.g., about 95% Ag and 5% Al) and an internal braze alloy of a Ti braze alloy (e.g., TiBraze 200). The internal braze alloy may be exposed to reactive materials (e.g., reactive metal vapors and/or salt vapors and/or liquids) in the sealed vessel and may not be exposed to air outside the sealed vessel. The first braze alloy in the top metal-to-ceramic joint 355 may be exposed to the air outside of the sealed vessel without being exposed to the reactive material in the sealed vessel. In some examples, the bottom metal-to-ceramic joint 315 may also include a first braze alloy and an internal braze alloy (as described above for joint 355).

The first metal sleeve 310 is joined with a conductor (e.g., current lead, such as a negative current lead) 350 via a first metal-to-metal joint (e.g., solder, braze) 345. The conductor may comprise a low carbon stainless steel, such as 304L stainless steel, for example, or a low carbon steel or Ni alloy (e.g., Ni 201). The second metal sleeve 340 is joined with the metal collar (e.g., 304L SS)320 via a second metal-to-metal joint (e.g., solder, braze) 325. The metal collar 320 is joined to a container (e.g., at a cell lid containing, for example, 304L SS) 330 via a third metal-to-metal joint (e.g., solder, braze) 335. The seal encloses a chamber 360 of the container, which chamber 360 may contain reactive materials, reactive liquids such as electrochemical cells, and gases, for example.

The metal-to-metal joint may include Bni braze containing 70 wt% or more Ni; for example, BNi-2, BNi-5b, or BNi-9 braze, a titanium-based braze alloy (e.g., TiBraze200), TiZrNi, TiNi-70, a silver-aluminum braze alloy (e.g., an alloy having a ratio of 19:1Ag: Al), a silver alloy, an aluminum alloy, an alloy containing at least silver, and/or an alloy containing at least aluminum. In some embodiments, the second metal-to-metal joint comprises BNi braze or a titanium-based braze alloy (e.g., tipize 200). In some embodiments, the first metal-to-metal joint and the second metal-to-metal joint comprise BNi braze or a Ti braze alloy. In some embodiments, each metal-to-metal joint comprises a BNi braze, a Ti braze alloy, and/or an Ag-Al braze alloy. In some examples, the metal collar 320 is welded to the container or integrally formed as part of the container.

Although described as a metal sleeve, in some embodiments, one or both of

metal sleeves

310 and 340 may be provided as a metal collar. In various embodiments, the seal illustrated in fig. 3 may comprise a variety of materials. In one example, the ceramic component 305 comprises Al₂O₃The ceramic, the

joints

315 and 355 comprise Cu-Ag braze, and the

metal sleeves

310 and 340 comprise Fe-Ni alloys (e.g., Fe-Ni sleeves or collars). In one example, ceramic component 305 comprises AlN ceramic, and joints 315 and 355 compriseA copper braze containing a nickel-plated metallization layer, and the

metal sleeves

310 and 340 comprise nickel metal (e.g., Ni metal sleeves or collars). In one example, the ceramic component 305 comprises AlN ceramic, the

joints

315 and 355 comprise Cr-Ni braze with a metalized layer, and the

metal sleeves

310 and 340 comprise nickel metal (e.g., Ni metal sleeves or collars).

The seal 300 may be incorporated into the electrochemical cell 400, optionally in combination with additional features as illustrated in fig. 4. The electrochemical cell 400 includes a container including a lid 330 and a can 430. The vessel contains reactive materials that are maintained at elevated temperatures (e.g., greater than 200 ℃) during operation. The reactive material includes a material that reacts with the positive electrode 420 (e.g., Pb-Sb, Bi, Sb, or FeS)₂) An electrolyte 410 (e.g., a salt) in contact with the negative electrode 440 (e.g., Li, Na, Mg, Ca). A negative current collector 450 (e.g., foam) connects the negative electrode to the negative current lead 350, the negative current lead 350 extending through the seal 300 to the external environment. A liner 460 (e.g., a graphite crucible) may be provided between the can 430 and the active cell components (e.g., the electrolyte 410 and the positive electrode 420).

The seal 300 may include a number of features as illustrated in fig. 4. In one example, ceramic component 305 comprises AlN ceramic, joints 315 and 355 comprise Ti, TiH₂And/or Ti braze alloy activated Al-Ag braze, and the

metal sleeves

310 and 340 comprise an alloy 42 metal alloy having a nickel layer on a surface thereof (e.g., a nickel-plated alloy 42 metal sleeve). The thickness of the

metal sleeve assemblies

310 and 340 may be less than about 0.030 inches. In some examples, the metal sleeve has a thickness of less than or equal to about 0.025 inches, 0.02 inches, 0.015 inches, 0.01 inches, or less. In some examples, the metal sleeve has a thickness of between about 0.01 and 0.015 inches, between about 0.01 and 0.02 inches, or between about 0.01 and 0.025 inches. In one example, the ceramic component includes physical ion barrier features 1000 (as described further below) that may prevent or inhibit the formation of metal dendrites along the ceramic surface. In one example, the current lead 350 (e.g., negative current lead) comprises a Ni alloy, steel (e.g., low carbon steel), or stainless steel (e.g., 304L SS alloy) and includes stainless steel(e.g., 304L SS) metal collar 320. The current lead 350 may include a feature, such as a shoulder, that is an integral part of the current lead and serves as a surface for brazing the top metal sleeve 310. The top metal-to-metal joint 345 between the current lead 350 and the top metal sleeve 310 may comprise an Ag-Al braze (e.g., -95% Ag and-5% Al), may comprise a Ni-based braze alloy (e.g., BNi-9 braze), or may comprise, for example, a Ti-based braze alloy (e.g., tibize 200). The bottom metal-to-metal joint 325 between the bottom metal sleeve 340 and the metal coupler 320 may comprise an Ag-Al braze (e.g., -95% Ag and-5% Al) or may comprise a Ni-based braze alloy (e.g., BNi-9 braze) or a Ti braze alloy (e.g., TiBraze200), for example.

The container of monomer may comprise a gas portion within between the liquid portion and the seal. In some examples, the reactive material from the liquid portion may evaporate into the gas portion, eventually contacting the seal. Additionally, liquid and/or ions may flow from the negative electrode along the surface of the negative current lead to the seal. These processes can cause undesirable corrosion when particles of reactive material contact the seal. Accordingly, a shield 500 may be provided to inhibit vapor, liquid, and/or ions from flowing from the liquid portion to the seal.

Fig. 5 illustrates an electrochemical cell including a shield 500, the shield 500 being shaped to inhibit or shield vapor from flowing from the liquid portion to the seal. The shield 500 extends into the gas portion between the liquid portion and the seal. To cause vapor to flow from the liquid portion at the bottom of the image (e.g., at a point near the center) to the seal at the top, the vapor may follow a path outward, around the shield, then inward toward the center, and up to the top of the seal. This path is illustrated by path 510, path 520, path 530, and path 540, respectively. The shield may partially or completely shield and/or block the seal and the liquid portion from separating from each other. Conversely, if there is no shroud, the gas flows directly up path 550, sharing path 540 to the seal. The latter path may provide less resistance to gas flow, as discussed in more detail below.

By allowing a small gap between the shroud and surrounding walls, the shroud can force the gas to flow along a narrow path of each segment; in general, the width of the path may be assigned a parameter w, which may have a variable value (e.g., in some cases, w is less than or equal to about 1cm, or less than or equal to about 2mm, or less than or equal to about 1 mm). The amount of gas flowing along the infinitesimal small distance dL of one of the paths may be proportional to the cross-sectional area through which the path flows. The smaller the area, the more restricted the airflow; in addition, the longer the length of gas flow, the more its flow may slow down. The shield may extend from the conductor. The shield may extend from the conductor a distance greater than or equal to about 1, 1.5, 2, 3, 4, 5 or more times the width of the conductor. In some examples, the shield extends from the conductor to within an infinitesimal distance of the vessel wall.

The extent to which the gas flow is restricted to a longer path by the shroud can be estimated by a parameter called the "effective gas diffusion path" or EGDP. EGDP may be defined as the integral of a path between two points along a reverse cross-sectional area (e.g., from a liquid to a seal) through which gas may flow. For example, on a path 510 in a circularly symmetric cell, with a radius r from the center and a path width w, the region may be estimated as the perimeter of a circle of width w multiplied by radius r. Under the assumption of a radially symmetric monomer/shroud geometry, then the infinitesimal EGDP may be approximated as

And may be integrated through each path

The complete EGDP is estimated. The unit of EGDP is 1/length, and a larger EGDP value may correspond to a longer effective distance through which vapor may flow. For example, given an inner radius r from the current wire₁To the outer radius r of the tank₂And the path returned (

approximate paths

510, 520, and 530, with path 520 radius r₂Along length L) from liquid toThe EGDP of the path portion of the seal can be estimated as

(ignoring second order terms, e.g. O (w)²)). To at r₁And r₂The path 550 of the upward travel distance L in the annular region in between performs a similar integration, resulting in an EGDP of

This may be a significantly smaller value than with a shield. The path 540 within the seal is common to both configurations and is therefore negligible. For example, the shield may increase the EGDP from the liquid portion to the seal by greater than or equal to about 10%, about 15%, about 20%, about 30%, or about 50% relative to the same monomer without the shield. For example, a simple shield such as the shield depicted in fig. 5 may have an EGDP of the monomer from about 6.35cm^-1Increasing to about 7.30cm^-1Or more. In some examples, the EGDP from the liquid portion to the seal is at least about 1cm^-1、2cm^-1、3cm^-1、4cm^-1、5cm^-1、6cm^-1、7cm^-1Or larger. In one example, the EGDP from the liquid portion to the seal is 7cm^-1Or larger.

Further increases in EGDP may be achieved using more complex shroud designs. For example, fig. 6 illustrates a single body comprising a more complex shield system comprising a plurality of shields. A first shield 502 is connected to the central negative current lead and a second shield 504 is connected to the wall of the cell container joined to the lid. Both shrouds include a plurality of alternating convex and concave portions to provide a long and tortuous path from the liquid portion to the seal. For example, the path may be S-shaped. For example, such a path may have a length greater than or equal to about 1.2, 1.5, 1.7, 2, 3, or 5 times the width of the container.

The shrouds provided herein may be shaped to provide additional benefits. For example, fig. 7 illustrates a shroud 506 that includes a lip 508 at an end thereof. The lip is shaped to inhibit the flow of liquid from the liquid portion to the seal (e.g., the liquid is splashed or spread along the solid surface, such as by capillary forces). For example, liquid with a moderate surface wetting angle can be prevented or impeded from flowing around the edges of the shroud.

The shield may also provide protection against the flow of ions along the surface of the negative current conductor to the seal. For example, fig. 8 illustrates a shroud 512 configured to increase the Effective Ion Diffusion Path (EIDP) for ions to travel from the liquid portion at the bottom of the image to the seal at the top. A first path 514 along the surface of the shroud 512 and the negative current lead to the seal is compared to a second path 516 running along the surface of the negative current lead. The EIDP may be defined as a non-dimensional parameter given by the integral of the path between two points along the reverse perimeter (e.g. from the liquid to the seal) through which particles flowing along the surface through the path may flow. For example, an infinitesimal EIDP may be approximated as being an infinitesimal EIDP when flowing along a radial path from the center of a circle to its perimeter

Where r is the radius of the circle. The complete integral will then be on the path

If the distance from the liquid part to the seal is L in FIG. 8, the radius of the current lead is r₁Radius of the shield being r₂And assuming circular symmetry, the EIDP of path 516 is approximately

And the EIDP of path 514 is the same value plus about representing the EIDP added from the shroud

The additional shield may further increase the EIDP by causing the ions to repeatedly flow back and forth. For example, a shield or shields in such a system may provide greater than or equal to about 30%, about 40%, about 50%, about 70%, about 75%, about 80%, about 90% compared to the same system without a shieldOr an increase in EIDP of 100%. In some examples, the effective ion diffusion path length is increased by about 75% or more. For example, the EIDP with the shroud may be greater than or equal to about 1, about 1.5, about 2, about 3, about 4, or about 5. In one example, the monomer without the shroud has an EIDP of 1.17 and the same monomer with the shroud as illustrated has an EIDP of 1.60. In a second example, multiple shrouds were provided, resulting in an EIDP of 2.24. More complex structures, such as the S-shaped structure of fig. 6, may provide further increases in EIDP.

An additional feature that may be provided by the shrouds disclosed herein is cathodic protection. For example, referring to fig. 4, the shroud 500 blocks vapor from the liquid portion 410 from traveling along a straight path to the seal 300. Instead, the vapor is directed to the outer edge of the container, immediately adjacent to the wall 430 of the can. The wall 430 of the can be in electrical communication with the positive electrode. Thus, atomic metal vapor from the liquid portion can be oxidized by contact with a positive current source to the wall. The walls may include an ion-conducting membrane (e.g., comprising salts from the electrolyte and/or previous vapor-wall interactions) such that the liquid metal atoms may be oxidized to salts upon contact with the walls. For example, the ion-conducting membrane may conduct ions between the wall and the liquid portion. These interactions may inhibit the flow of reactive metal atoms from the liquid portion to the seal. A shield configured to direct vapor along the conductive vessel wall, particularly in close proximity (e.g., about 5mm or less), and extending a distance (e.g., about 1cm or more), may enhance this effect.

Fig. 9 illustrates a configuration including a plurality of shrouds, with a first shroud 522 attached to the negative current lead and a second shroud 524 disposed between the first shroud 522 and the liquid portion 526, the second shroud 524 being in contact with the positive current lead. To reach the seal at the top of the image, the vapor may pass through the second shield 524, and the second shield 524 acts to oxidize the reactive metal vapor to less reactive salt ions, thereby reducing seal corrosion.

The ceramic portion of the seal may include measures to reduce the flow of metal species, including electromigration of metal ions from the braze material along the surface of the ceramic component. The seal may comprise a ceramic component having a tubular configuration. The tubular structure may have any cross-sectional geometry including, but not limited to, circular, oval, triangular, square, rectangular, or polygonal. In some embodiments, the ceramic component is annular or "toroidal". The inner dimension of the tubular structure may be greater than or equal to the outer dimension of the current lead such that the ceramic component may surround the current lead (e.g., the ceramic component may be a ring that fits over the outer surface of the current lead). The ceramic component may be in partial contact with the outer surface of the current lead, may be in partial contact, or may be out of contact. The seal may be formed by brazing metal sleeves to the top and bottom of the outer surface of the ceramic component (e.g., the surface of the ceramic component not exposed to the reactive material within the sealed container) to form a first braze joint and a second braze joint. Alternatively or additionally, the first and second braze joints may be formed by brazing the metal sleeve to the top and bottom of the inner surface of the ceramic component, by brazing to the inner top and outer top edges of the ceramic component, by brazing to the inner and outer bottom edges of the ceramic component, or by brazing the metal sleeve to the top and bottom edges of the ceramic component. The first and second braze joints may surround the ceramic component and form a hermetic and hermetic seal along an outer surface of the ceramic component. The braze joint may conceal or cover a portion of the outer surface of the ceramic component. A portion of the ceramic component between the first and second braze joints may not be covered by the first and second braze joints and may be exposed to an ambient environment. The ambient environment may be any environment outside the monomer. For example, the exposed surface of the ceramic component between the first braze joint and the second braze may be outside the monolithic body without contacting the reactive vapor or the reactive material within the monolithic body. The ceramic component exposed to the ambient environment may have a surface extending from the first soldered joint to the second soldered joint and surrounding the current lead. The ceramic component may or may not be in contact with the current lead. In some examples, a surface of the ceramic component extending between the first braze joint and the second braze joint is smooth (e.g., the surface may include a linear intercept between the first braze joint and the second braze joint) and may result in a minimum surface area when compared to other possible surfaces that intercept both the first braze joint and the second braze joint. In some examples, a surface of the ceramic component extending between the first braze joint and the second braze joint has a protrusion that increases an area of an exposed surface of the ceramic component. A protrusion may be defined as one or more features that extend away from (e.g., at least partially orthogonal to) a theoretical or imaginary smooth surface (e.g., a reference surface) extending between a first braze joint and a second braze joint of a seal. In some embodiments, the protrusion may also be defined as one or more features that extend at least partially away from both the first and second braze joints of the seal.

Under some operating conditions, some braze materials may allow metal ions to flow across the surface of the ceramic component, which may lead to undesirable short circuits, for example, due to the formation of metal dendrites as the ions reach the distal electrode and are reduced to neutral metals. As this process repeats, dendrites can grow across the surface of the ceramic component, eventually forming a metallic connection between the oppositely polarized conductors, resulting in a short circuit. To suppress this, a physical ion blocker may be provided on the exposed surface of the ceramic component and/or integrated into the design of the ceramic component. For example, the seal 300 of fig. 4 illustrates a physical ion barrier 1000 that includes a plurality of protrusions on an extended surface that is substantially perpendicular to a reference surface extending between a first braze joint and a second braze joint. The protrusion may be formed by one or more exposed surfaces of the ceramic component that are substantially parallel, substantially perpendicular, and/or at an acute angle to a reference surface extending from the first braze joint to the second braze joint. The plurality of protrusions may each include a first surface portion, a second surface portion, and/or a third surface portion. The first surface portion may extend away from an exposed surface of the ceramic component that is perpendicular, substantially perpendicular, or angled to a reference surface of the ceramic component that extends from the first braze joint to the second braze joint. For example, the protrusions may be angled less than or equal to about 20 degrees from a right angle, less than or equal to about 5 degrees from a right angle, or less than or equal to about 1 degree from a right angle. The second surface portion may be parallel, substantially parallel or at a defined slope with respect to a reference surface of the ceramic component extending from the first braze joint to the second braze joint. The third surface portion may extend towards the reference surface of the ceramic component. The electric field vector may be parallel to the reference surface and directed from the first ceramic to metal braze joint to the second ceramic to metal braze joint. One of the ceramic to metal braze joints may be in electrical communication with the positive electrode. Without the protrusions, the ions may be pulled by the electric field between the braze of the positive polarization sleeve (e.g., 340) and the braze of the negative polarization sleeve (e.g., 310). The protrusions may cause ions traveling along the exposed surface of the ceramic component to move perpendicular to, or at least partially against, the electric field, thereby slowing or stopping the progression of the ions. Although two protrusions are illustrated, more or fewer protrusions may be used, such as a single protrusion (e.g., around the outer perimeter of the ceramic component), or three or more such protrusions. The ceramic component and the protrusion may be a single component (i.e., the ceramic component and the protrusion may be one continuous material). Alternatively or additionally, the protrusion may be a plurality of components that are adhered together and/or to the ceramic component by welding, brazing, ceramic glue or cement or other bonding methods. In some examples, the length or angle of the protrusions may be different from one another. The protrusion may extend a distance of greater than or equal to about 0.5 millimeters (mm), 1mm, 2mm, 3mm, 4mm, 6mm, 8mm, 10mm, or more from a reference surface of the ceramic component that extends from the first braze joint to the second braze joint.

Fig. 10A, 10B and 10C illustrate various ceramic components that include a physical ion blocker. Fig. 10A, 10B and 10C illustrate two-dimensional cross-sections of radial symmetry of a ceramic component including a physical ion blocker, where the radial symmetry line passes perpendicularly through the center of each image. Fig. 10A illustrates a ceramic component 1010 that includes a physical ion blocker 1012. The physical ion blocker 1012 includes angled protrusions to form a void or groove 1014 oriented downward in a direction toward the positive side of the electric field 1016. As the ions travel along the surface, they are redirected in a direction having a vector component opposite the electric field vector when the direction of the electric field 1016 reaches the physical ion blocker, as indicated by the reverse arrow 1018. Thus, the path from bottom to top approaches the top first, then reverses the process, and then resumes movement to the top. Because the motion is in the opposite direction to the electric field, the positive ions will be effectively opposed by the field, thereby suppressing electromigration. Fig. 10B shows another embodiment, in which the ceramic component 1020 includes a physical ion blocker 1022 having protrusions at an acute angle to the surface of the ceramic component and forming an angled slot 1024 (downward) generally toward the positive electric field source. This angled recess (or gap) provides a similar effect as the parallel recess 1014, in that ions moving along the surface above the recess may travel at least partially along the surface of the ceramic component against the perpendicular electric field. Fig. 10C shows a third example, where the ceramic part 1030 comprises a physical ion blocker 1032, the physical ion blocker 1032 comprising a protrusion defining a recess 1034 defining a slope substantially perpendicular to the surface of the ceramic part. As shown herein, the physical ion barrier may be formed as an integral part of the ceramic component or integrated with the ceramic component. Alternatively, the physical ion blocker may be attached to the ceramic component.

A modification to the current lead (e.g., a negative current lead) is illustrated in fig. 11A. Fig. 11A illustrates two embodiments of a Negative Current Lead (NCL) including a coupler for bonding to a metal sleeve. In the first embodiment 1110, the coupler 1115 is provided as a separate piece that is attached (e.g., welded) to the NCL. In the second embodiment 1120, the coupler 1825 is provided as an integral part of the NCL, forming a shoulder to which the sleeve may be joined (e.g., brazed or welded).

Fig. 11B illustrates additional features that may be included in the current lead, such as the NCL. In some embodiments, an NCL comprising a uniform cylindrical top portion may be provided. Such a top may be difficult to restrain, for example, when attaching the negative current collector on the opposite side of the NCL (e.g., to a threaded connector), or when making other attachments to the NCL. To more effectively constrain the NCL, a pair of substantially flat parallel surfaces may be provided at the ends of the NCL. Fig. 11B illustrates such a feature, as illustrated by front view 1830 and side view 1840. By breaking the cylindrical symmetry, these surfaces provide an effective gripping point, such as by a wrench, for example. This allows torque to be applied to rotate or stabilize the NCL when adjusting the cell or NCL or when attaching other components (e.g., negative current collector).

In some examples, the brazed ceramic seal includes a subassembly. The subassembly may comprise an insulating ceramic bonded to one or more (e.g. two) flexible spring-like or accordion-like components (referred to herein as metal sleeves). After the subassembly is manufactured, the sleeve may be brazed or welded to other cell assemblies, such as the negative current lead, the cell cap, and/or a collar bonded (welded) to the cell cap. Alternatively, all joints can be created on the complete cap assembly by brazing (e.g., if the tolerance limits are tight enough). The chemical compatibility between the brazing material and the atmosphere to which the material will be exposed, as well as the thermal robustness during high temperature operation and thermal cycling, can be evaluated during the design of the subassembly. In some cases, the ceramic material is aluminum nitride (AlN) or silicon nitride (Si)₃N₄) And the braze is a titanium alloy, a titanium-doped nickel alloy, a zirconium alloy, or a zirconium-doped nickel alloy. In some cases, the ceramic material is aluminum nitride (AlN) and the braze is a silver aluminum alloy.

Fig. 12 shows a schematic view of a brazed ceramic seal having a material that is thermodynamically stable with respect to the monolithic inner 1205 and/or outer 1210 environments. Such materials may not include a coating. Various materials may have mismatched CTEs that may be accommodated with one or more geometric or structural features 1215 (e.g., flexible metal bends, tabs, or folds). One end of CTE compliant feature 1215 may be welded to monolithic housing 1220 (e.g., 400 series stainless steel) while the other end is brazed 1225 to first metallized surface 1230 of ceramic material 1235. The ceramic material 1235 may be, for example, aluminum nitride (AlN), Boron Nitride (BN), or yttria as described herein(Y₂O₃). The ceramic material may be brazed to the current collector (conductive feed-through) 1240 via a braze joint 1245. The braze joint 1245 may comprise iron (Fe), nickel (Ni), titanium (Ti), or zirconium (Zr), for example. The braze joint 1245 may be in contact with a second metallized surface of the ceramic 1250 (e.g., titanium or titanium nitride). Several layers of material placed adjacent to each other can result in a CTE gradient that can attenuate the mismatch.

Fig. 13 illustrates a seal in which the ceramic and/or braze material is thermodynamically stable with respect to the internal 1205 and external 1210 environments. In some cases, a coating may be applied to the interior 1305 and/or the exterior 1310 of the seal or enclosure assembly.

Fig. 14, 15, 16 and 17 show further examples of brazed ceramic seals. In some examples, the seal extends a greater distance on the housing. Fig. 14 illustrates an example of a monolithic on-body seal that may advantageously not include a coating, include CTE mismatch-compliant features, and/or provide enhanced structural stability against vibration and mechanical forces during handling, manufacturing, or shipping. In this example, the can 1405 may be sealed to separate the current collectors 1410. This arrangement can hermetically seal the inner portion 1415 of the cell from the outer portion 1420 of the cell. The assembly of the seal may be arranged vertically and may include a first braze joint 1425, a ceramic 1435, a first metalized surface 1430 of the ceramic, a second braze joint 1440, and a second metalized surface 1445 of the ceramic.

Fig. 15 illustrates a seal 1520, where the seal 1520 may provide structural stability against vibration and mechanical forces during handling, manufacture, and shipping. In this example, a CTE-accommodating feature 1505 is disposed between the housing 1510 and the current collector 1515. The seal 1520 may include a ceramic and two brazed joints in contact with the metallized surface of the ceramic. In some examples, the seal is coated on the inner side 1525 and/or the outer side 1530. In some examples, the coating(s) may include yttrium oxide (Y)₂O₃)。

Fig. 16 shows a seal 1610 with a secondary mechanical load bearing assembly 1605. In some cases the load bearing assembly is electrically insulated. In some cases, the load bearing assembly does not form a hermetic seal. A seal 1610 (e.g., comprising ceramic, two braze joints in contact with a metallized surface of the ceramic, etc.) may hermetically seal the single housing 1615 to separate the current collectors 1620.

Fig. 17 shows an example of a secondary seal 1705 (e.g., in the event of a failure of the primary seal 1710). The secondary seal may fall onto and/or bond with the primary seal in the event of failure of the primary seal. In some examples, the secondary seal comprises glass that melts and becomes flowable in the event of failure of the primary seal. The melted secondary seal can pour down onto the failed primary seal and block the leak. In some examples, the seal 1705 and/or the seal 1710 may be axisymmetric (e.g., annular about a vertical axis through an aperture in the unitary cover).

The devices, systems, AND METHODS of the present disclosure may be combined WITH or modified by other devices, systems, AND/or METHODS, such as, FOR example, the BATTERY assemblies described in U.S. patent No. 3,663,295 ("STORAGE BATTERY electric"), U.S. patent No. 3,775,181 ("LITHIUM STORAGE CELLS WITH A FUSED electric"), U.S. patent No. 8,268,471 ("HIGH-AMPERAGE ENERGY STORAGE DEVICE WITH LIQUID METAL NEGATIVE electric AND METHODS"), U.S. patent publication No. 2011/0014503 ("ALKALINE EARTH METAL ION BATTERY"), U.S. patent publication No. 2011/0014505 ("LIQUID ELECTRODE BATTERY electric"), U.S. patent publication No. 2012/0104990 ("ALKALI METAL ION BATTERY WITH BATTERY electric"), U.S. patent publication No. 2014/0099522 ("LOW-BATTERY LIQUID METAL BATTERY FOR GRID anode"), AND PCT/US2016/021048 BATTERY FOR anode REACTIVE MATERIAL DEVICES, each of the above patents and patent publications is incorporated herein by reference in its entirety.

The energy storage device of the present disclosure may be used in a grid scale scenario or an independent use scenario. The energy storage devices of the present disclosure may be used in some instances to power vehicles such as scooters, motorcycles, cars, trucks, trains, helicopters, airplanes, and other mechanical devices such as robots.

It is to be understood that the terminology used herein is for the purpose of describing particular embodiments and is not intended to limit the scope of the present invention. It should be noted that, as used herein, the singular forms "a," "an," and "the" include plural referents unless the context clearly dictates otherwise. Moreover, unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

While preferred embodiments of the present invention have been shown and described herein, it will be readily understood by those skilled in the art that such embodiments are provided by way of example only. Numerous variations, changes, and substitutions will now occur to those skilled in the art without departing from the invention. It should be understood that various alternatives to the embodiments of the invention described herein may be employed in practicing the invention. It is intended that the following claims define the scope of the invention and that methods and structures within the scope of these claims and their equivalents be covered thereby.

Claims

1. A high temperature device, comprising:

a vessel comprising a lumen, wherein the lumen comprises a reactive material, wherein the reactive material comprises a gas portion and a liquid portion, and wherein the reactive material is maintained at a temperature of at least 200 ℃;

a seal sealing the interior cavity of the vessel from an environment external to the vessel, wherein the seal comprises a ceramic component, and wherein the seal is exposed to the reactive material and the environment external to the vessel;

a conductor extending from the environment external to the container, through the seal, to the interior cavity of the container;

a shield connected to the conductor and located within the gas portion of the interior cavity of the vessel, the shield extending a distance from the conductor, and wherein the shield is configured to inhibit or block vapor from flowing from the liquid portion of the reactive material to the seal; and

a first metal sleeve coupled to the conductor and the ceramic component, wherein the first metal sleeve is coupled to the ceramic component by a first braze joint comprising a first braze compound, and wherein the first braze compound comprises an alloy of silver and aluminum.

2. The high temperature device of claim 1, wherein the conductor is a negative current lead.

3. The high temperature device of claim 2, further comprising a negative current collector within the container, wherein the negative current collector is in contact with the reactive material and attached to the negative current lead.

4. The high temperature device of claim 1, further comprising a second metal sleeve coupled to the ceramic component, wherein the second metal sleeve is coupled to the vessel or to a collar that is joined to the vessel, wherein the second metal sleeve is coupled to the ceramic component by a second braze joint comprising a second braze material, and wherein the second braze material comprises an alloy of silver and aluminum.

5. The high temperature device of claim 4, wherein the alloy of silver and aluminum comprises a ratio of silver to aluminum of less than or equal to 19 to 1.

6. The high temperature device of claim 5, wherein one or both of the first braze and the second braze further comprises a titanium braze alloy.

7. The high temperature device of claim 4, further comprising an internal braze disposed adjacent to the first braze joint, the second braze joint, or both the first braze joint and the second braze joint, wherein the internal braze is exposed to the interior cavity of the vessel.

8. The high temperature device of claim 7, wherein the internal braze comprises a titanium braze alloy.

9. The high temperature device of claim 8, wherein the titanium brazing alloy comprises 19-21 weight percent zirconium, 19-21 weight percent nickel, 19-21 weight percent copper, and the remaining weight percent comprises at least titanium.

10. The high temperature device of claim 4, wherein the second metal sleeve is coupled to the vessel or the collar by a third braze.

11. The high temperature device of claim 10, wherein the third braze comprises a nickel-based braze or a titanium-based braze, and wherein the nickel-based braze comprises greater than or equal to 70 weight percent nickel.

12. The high temperature device of claim 11, wherein the nickel-based braze comprises BNi-2 braze, BNi-5b braze, or BNi-9 braze.

13. The high temperature device of claim 11, wherein the first metal sleeve is coupled to the conductor by a fourth braze.

14. The high temperature device of claim 13, wherein the fourth braze is a nickel-based braze, a titanium-based braze, or an alloy of silver and aluminum.

15. The high temperature device of claim 1, wherein the alloy of silver and aluminum further comprises a wetting agent.

16. The high temperature device of claim 15, wherein the wetting agent comprises titanium.

17. The high temperature device of claim 1, wherein the ceramic component comprises aluminum nitride.

18. The high temperature device of claim 17, wherein the ceramic component further comprises greater than or equal to 3 weight percent yttria.

19. The high temperature device of claim 17, wherein the ceramic component further comprises 1 to 4% by weight yttria.

20. The high temperature device of claim 4, wherein the first metal sleeve and the second metal sleeve comprise alloy 42.

21. The high temperature device of claim 20, wherein the conductor or the collar comprises stainless steel.

22. The high temperature device of claim 20, wherein the thickness of the first and second metal sleeves is less than or equal to 0.020 inches.

23. The high temperature device of claim 21, wherein the stainless steel comprises 304L stainless steel.

24. An electrochemical cell, comprising:

a container comprising a lumen, wherein the lumen comprises a reactive material, and wherein the reactive material is maintained at a temperature of at least 200 ℃;

a seal sealing the interior cavity of the vessel from an environment external to the vessel, wherein the seal comprises a ceramic component exposed to both the reactive material and the environment external to the vessel;

a current lead extending from the interior cavity of the container through the seal to the environment outside the container;

a first metal sleeve coupled to the current lead and the ceramic component; and

a second metal sleeve coupled to the ceramic component and the vessel or to a collar joined to the vessel,

wherein the ceramic component comprises a physical ion blocker on a surface of the ceramic component, wherein the physical ion blocker comprises one or more protrusions located on the surface of the ceramic component exposed to the environment outside of the vessel.

25. The electrochemical cell of claim 24, wherein the physical ion blocker is shaped to inhibit electromigration along the surface of the ceramic component.

26. The electrochemical cell of claim 24, wherein the physical ion blocker is shaped to inhibit formation of metal dendrites across the surface of the ceramic component.

27. The electrochemical cell of claim 24, wherein the first and second metal sleeves are coupled to the ceramic component by first and second braze, respectively.

28. The electrochemical cell of claim 27, wherein the surface of the ceramic component is an exposed surface of the ceramic component between the first braze and the second braze, and wherein the physical ion barrier is shaped such that a shortest path from the first braze to the second braze along the exposed surface of the ceramic component includes a path segment that is at least partially away from both the first braze and the second braze.

29. The electrochemical cell of claim 27, wherein the first and second braze solders each comprise an alloy of silver and aluminum.

30. The electrochemical cell of claim 24, wherein the current lead is a negative current lead.

31. The electrochemical cell of claim 24, wherein the physical ion barrier is an integral part of the ceramic component, and wherein the one or more protrusions protrude from a reference surface of the ceramic component.

32. The electrochemical cell of claim 31, wherein the one or more protrusions comprise a plurality of protrusions defining grooves.

33. The electrochemical cell of claim 31, wherein the one or more protrusions extend from the reference surface of the ceramic component a distance greater than or equal to 2 mm.

34. The electrochemical cell of claim 31, wherein the one or more protrusions comprise a long dimension and a short dimension, and wherein the long dimension defines a chamfer disposed at an angle substantially orthogonal to the reference surface of the ceramic component.

35. The electrochemical cell of claim 31, wherein the one or more protrusions define a slope disposed at an acute angle relative to the reference surface of the ceramic component and facing a source of positive electric field.

36. The electrochemical cell of claim 31, wherein the one or more protrusions comprise a first portion protruding from the reference surface of the ceramic component and a second portion defining a slope extending parallel to the reference surface of the ceramic component and toward a positive electric field source.

37. The electrochemical cell of claim 36, wherein the positive electric field source is the body of the container in electrical communication with a positive electrode.

38. The electrochemical cell of claim 24, wherein the electrochemical cell is a battery, and wherein the battery comprises a negative electrode, a positive electrode, and a liquid electrolyte.

39. The electrochemical cell of claim 38, wherein at least one of the negative electrode and the positive electrode is a liquid metal electrode.

40. The electrochemical cell according to claim 38, wherein the liquid electrolyte is a molten halide electrolyte.

41. A high temperature device, comprising:

a seal that seals the interior cavity of the vessel from an environment external to the vessel, wherein the seal comprises a ceramic component, and wherein the seal is exposed to both the reactive material and the environment external to the vessel;

a metal sleeve coupled to the conductor and the ceramic component, wherein the metal sleeve is coupled to the ceramic component by a braze joint comprising a braze, and wherein the braze is formed of a material that: the material is substantially non-reactive with air and prevents diffusion of air into the container when the reactive material is maintained at a temperature of at least 200 ℃ for a period of at least 1 day.

42. The high temperature device of claim 41, wherein the braze is ductile.

43. The high temperature device of claim 41, further comprising an internal braze, and wherein the internal braze contacts and protects the braze from the reactive material.

44. The high temperature device of claim 43, wherein the internal braze is an active metal braze.

45. The high temperature device of claim 41, wherein the diffusion of air into the container is at most 1x10^-8Atmospheric pressure-cubic centimeters per second.

46. The high temperature device of claim 42, wherein the braze is an alloy of at least two different metals.

47. The high temperature device of claim 1 or 41, wherein the high temperature device is a battery, and wherein the battery comprises a negative electrode, a positive electrode, and a liquid electrolyte.

48. The high temperature device of claim 47, wherein at least one of the negative electrode and the positive electrode is a liquid metal electrode.

49. The high temperature device of claim 47, wherein the liquid electrolyte is a molten halide electrolyte.

50. The high temperature device of claim 1, wherein the steam is a reactive metal vapor.